Polyribosomes Conserved during Desiccation of the Moss Tortula ruralis Are Active

During desiccation of the moss Tortula ruralis (Hedw.) (Gaertn, Meyer and Scherb) polyribosomes are conserved. On rehydration, protein synthesis is rapidly resumed. In the presence of protein synthesis initiation inhibitors ribosome run-off from the conserved polyribosomes takes place, confirming that these retain their activity as intact structures during desiccation.     

Membrane Organization of the Desiccation-Tolerant Moss Tortula ruralis in Dehydrated States

Membrane organization of the desiccation tolerant moss Tortula ruralis was studied in several intensely dehydrated states (75% relative humidity [RH], 90% RH, plasmolysis in molar salt, freezing to −20°C) by ³¹P nuclear magnetic resonance and ultrastructural analyses. Both methods revealed that even at 75% RH (−400 bars), the moss cellular membranes retained extended phospholipid bilayers. Ultrastructural analyses of the fully hydrated moss showed an extensive proliferation of membrane vesicles in the endoplasmic reticulum. During dehydration, these vesicles form layers of membrane under the plasmalemma and in some cases appear to fuse with the surface membrane. This suggests that these vesicles may serve as a reservoir of membranes to accommodate for membrane surface area changes during desiccation and subsequent rehydration.     

Plant Desiccation and Protein Synthesis : VI. Changes in Protein Synthesis Elicited by Desiccation of the Moss Tortula ruralis are Effected at the Translational Level

Upon rehydration of the moss Tortula ruralis following desiccation at a rapid or slow rate, there is increasing utilization of newly synthesized-poly(A)⁺ RNA for protein synthesis. Initially, poly(A)⁺ RNA conserved in the dry moss is associated with polysomes, but by 2 hours of rehydration there is an overwhelming recruitment of newly synthesized poly(A)⁺ RNA, at the expense of conserved messages. In rehydrated moss, there is a marked synthesis in vivo of new proteins, which are separable by two-dimensional electrophoresis, and identifiable by fluorography. These new proteins, termed rehydration proteins, are synthesized after both rapid and slow desiccation, but their synthesis persists longer after rapid desiccation. The protein patterns obtained following in vitro translation of bulk RNA from hydrated, desiccated, and rehydrated moss were qualitatively identical. Thus the differences in protein patterns observed in vivo must result from preferential selection of specific mRNAs from the same pool, which is indicative of control of protein synthesis at the translational level. The implications of these observations in relation to the response of the moss to drying in its natural environment are discussed.     

Protein Synthesis Related to Cold Temperature Stress in the Desiccation-Tolerant Moss Tortula ruralis

Incubation of hydrated Tortula ruralis (Hedw.) Gaertn., Meyer. Scherb. at temperatures down to 2°C resulted in an accumulation of polyribosomes and a decrease in single ribosomes. No changes in the levels of ribosomal subunits were detected. On rehydration of slowly dried moss, which contains no polyribosomes, these were reormed at 2, 8 and 20°C. Rapid incorporation of labelled leucine into protein was observed on reintroduction of the desiccated plant o water at 20°C and there was significant, but much reduced, ncorporation at 2°C. Previously undesiccated moss was also able o take up radioactive leucine and to synthesize protein at 2 and -2.5°C. Changes in the rate of protein synthesis at low temperature were not detected in cold hardened (winter collected or incubated at 2°C) T. ruralis. The moss appears to be adapted to survive freezing wear round and even summer-collected moss can conduct protein synthesis at low temperatures: seasonal cold hardiness changes do lot appear to take place.     

Plant Desiccation and Protein Synthesis: III. Stability of Cytoplasmic RNA during Dehydration, and Its Synthesis on Rehydration of the Moss Tortula ruralis

RNA species from the haploid gametophyte generation of the moss Tortula ruralis exhibit typical eukaryotic characteristics. The major ribosomal and soluble RNA species are stable during drying and rehydration. RNA synthesis occurs rapidly on reintroduction of the moss to water and incorporation into high molecular weight RNA fractions was detected after 20 to 30 minutes of rehydration and into low molecular weight fractions after 30-60 minutes. Newly synthesized ribosomal RNA was detected in ribosomes within 2 hours of rehydration, but not in polysomes. It is apparent that the ribosomal and transfer RNA conserved during desiccation is involved in the re-establishment of early protein synthesis during subsequent rehydration and that, initially, there is no requirement for newly synthesized material.     

Plant Desiccation and Protein Synthesis. IV. RNA Synthesis, Stability, and Recruitment of RNA into Protein Synthesis during Desiccation and Rehydration of the Desiccation-Tolerant Moss, Tortula ruralis

We have studied the effects of ATP and ADP on the oxidation of malate by coupled and uncoupled mitochondria prepared from etiolated hypocotyls of mung bean (Vigna radiata L.).

In coupled mitochondria, ATP (1 millimolar) increased pyruvate production and decreased oxaloacetate formation without altering the rate of oxygen consumption. ATP also significantly decreased oxaloacetate production and increased pyruvate production in mitochondria that were uncoupled by carbonyl cyanide p-trifluoromethoxyphenyl hydrazone plus oligomycin.

In coupled mitochondria, ADP (1 millimolar) increased the production of both pyruvate and oxaloacetate concomitantly with the acceleration of oxygen uptake to the state 3 rate. The effects of ADP were largely eliminated in uncoupled mitochondria. These results indicate that, whereas the ADP stimulation of oxaloacetate and pyruvate production in the coupled mitochondria is brought about primarily as the result of the accelerated rates of electron transport and NADH oxidation by the respiratory chain in state 3, ATP has significant regulatory effects independent of those that might be exerted by control of electron transport.

     

Plant Desiccation and Protein Synthesis : V. Stability of Poly (A) and Poly (A) RNA during Desiccation and Their Synthesis upon Rehydration in the Desiccation-Tolerant Moss Tortula ruralis and the Intolerant Moss Cratoneuron filicinum

Upon desiccation of gametophytes of the desiccation-tolerant moss Tortula ruralis preexisting pools of poly(A)⁻ RNA (rRNA) remain inact, regardless of the speed at which desiccation is achieved. Preexisting poly(A)⁺ RNA pools (mRNA) are unaffected by slow desiccation but are substantially reduced during rapid desiccation. Poly(A)⁻ RNA involved in protein synthesis is also unaffected by desiccation, whereas the levels of polysomal poly(A)⁺ RNA in rapid- and slow-dried moss closely reflect the state of the protein synthetic complex in these dried samples.

Poly(A)⁻ RNA pools, both total and polysomal, are also stable during the rehydration of both rapid- and slow-dried moss. The total poly(A)⁺ RNA pool decreases upon rehydration, but this reduction is simply an expression of the normal turnover of poly(A)⁺ RNA in this moss. Analysis of polysomal fractions during rehydration reveals the continued use of conserved poly(A)⁺ RNA for protein synthesis. The rate of synthesis of poly(A)⁺ RNA upon rehydration appears to depend upon the speed at which prior desiccation is administered. Rapidly dried moss synthesizes poly(A)⁺ RNA at a faster rate, 60 to 120 minutes after the addition of water, than does rehydrated slowly dried moss. Recruitment of this RNA into the protein synthetic complex also follows this pattern. Comparative studies involving the aquatic moss Cratoneuron filicinum are used to gain an insight into the relevance of these findings with respect to the cellular mechanisms associated with desiccation tolerance.

     

On the Metabolism of Tortula ruralis Following Desiccation and Freezing: Respiration and Carbohydrate Oxidation

Recovery from desiccation by Tortula ruralis (Hedw.) Gaertn., Meyer and Scherb was accompanied by an immediate, rapid increase in respiration (measured as oxygen uptake) at 25.5°C or 3.5°C. The respiratory burst was greater on rehydration of moss which had been rapidly desiccated over silica gel than that which had been more slowly desiccated in atmospheres of high relative humidity. No respiration was observed in dry moss. Dried moss which had been placed in liquid nitrogen resumed respiration on rewarming and rehydration but moss which had been frozen in the hydrated state respired to a lesser extent and showed signs of freeze damage. In the initial stages of slow drying a slight increase in respiration was noted, followed by a gradual decrease as drought became more severe. In contrast to observations made on many higher plants under drought stress, this moss did not exhibit any changes in its starch and sugar content during or following desiccation, nor were there any changes in free proline levels. Using (1-¹⁴C)-glucose and (6-¹⁴C)-glucose, the relative activities of the Embden–Meyerhof–Parnas and pentose phosphate pathways in hydrated and rehydrated moss were determined, as were the activities of specific enzymes involved in these pathways. An increased activity of the Embden–Meyerhof–Parnas pathway of glucose oxidation on rehydration of Tortula was observed. The possible significance of this latter observation is outlined.     

Influence of Protoplasmic Water Loss on the Control of Protein Synthesis in the Desiccation-Tolerant Moss Tortula ruralis: Ramifications for a Repair-Based Mechanism of Desiccation Tolerance

Desiccation tolerance of the moss Tortula ruralis is characterized by a desiccation-induced change in gene expression that becomes evident upon rehydration. As reported earlier, this change in gene expression is apparently brought about by a change in the control of translation and does not include a major shift in mRNA abundance. A full qualitative and quantitative analysis of the alteration in gene expression, which is characterized by the loss of (or greater than fivefold decrease in) the synthesis of 25 hydration (h) proteins and initiation (or greater than fivefold increase) of the synthesis of 74 rehydration (r) proteins, is given in this report. Exposure to a desiccating atmosphere, for times that result in varying levels of water loss, enabled the determination that the control of synthesis of r proteins is different from the control of synthesis of h proteins. The r and h protein synthesis responses are internally coordinate, however. Similarly, the return to normal levels of h protein synthesis differs from that of the r proteins. The return to normal synthetic levels for all h proteins is synchronous, but the rate of loss of r protein synthesis varies with each individual r protein. Run-off translation of polysomes isolated from gametophytes during the drying phase demonstrates that there are no novel mRNAs recruited and no particular mRNA is favored for translation during desiccation. These findings add credence to the argument that translational control is the major component of the desiccation-induced alteration in gene expression in this plant, as discussed. Aspects of the response of protein synthesis to desiccation are consistent with the hypothesis that T. ruralis exhibits a repair-based mechanism of desiccation tolerance.     

Effects of Various Rates of Freezing on the Metabolism of a Drought-tolerant Plant, the Moss Tortula ruralis

The response of the drought-tolerant moss Tortula ruralis ([Hedw.] Gaertn., Meyer, Scherb.) to freezing and thawing at controlled rates has been studied. Slow freezing (at 3 C per hour to −30 C) of hydrated T. ruralis leads to only temporary, reversible changes in metabolism. These changes can be considered to result from desiccation due to extracellular ice formation. In contrast, rapid freezing in liquid N₂ and thawing in 20 C water leads to deterioration in all aspects of metabolism studied: ribosome, protein, and ATP levels decrease, and in vivo and in vitro protein synthetic activity is lost rapidly. Such changes probably result from intracellular ice formation. Following freezing and thawing at an intermediate rate (60 C per hour), only ATP levels and in vivo protein synthesis are reduced. The protein-synthesizing apparatus (the polyribosomes) remains intact and active in an in vitro protein-synthesizing system even 24 hours after one 60 C per hour freeze-thaw cycle. These metabolic responses are discussed in terms of the two-factor hypothesis of Mazur et al. (1972 Exp. Cell Res. 71: 345-355).     

Glutathione Status and Protein Synthesis during Drought and Subsequent Rehydration in Tortula ruralis

Glutathione status and its relationship to protein synthesis during water deficit and subsequent rehydration have been examined in the drought-tolerant moss, Tortula ruralis. During slow drying there is a small decrease in total glutathione but the percentage of oxidized glutathione (GSSG) increases. During rapid drying there is little change in total glutathione but a small increase in GSSG. On rehydration of slowly dried moss, GSSG rapidly declines to normal level. But when rapidly dried moss is rehydrated, there is an immediate, sharp increase in GSSG as a percentage of total glutathione. After 2 hours of rehydration GSSG starts declining and reaches a normal level in about 6 hours. When an increasing degree of steady state water deficit is imposed on the moss tissue with polyethylene glycol 6000, there is a progressive decrease in protein synthesis but an increase in oxidized glutathione. When 5 millimolar GSSG is supplied exogenously during rehydration of rapidly dried or slowly dried moss, protein synthesis is strongly inhibited. In vitro protein synthesis supported by moss mRNA is also inhibited by more than 85% by 150 micromolar GSSG. The role of glutathione status in water deficit-induced inhibition of protein synthesis is discussed.     

Protein Synthesis during Rehydration of Rapidly Dried Tortula ruralis: Evidence for Oxidation Injury

Rapidly dried Tortula ruralis, a drought-tolerant moss, is known to synthesize proteins on rehydration at a much lower rate than the slowly dried moss. The reasons for this low rate of protein synthesis are unclear. We have found that during rehydration of rapidly dried moss, there is a negative correlation between the rate of protein synthesis and the tissue levels of oxidized glutathione (GSSG) and lipid peroxidation. When rapidly dried moss, which is known to show extensive solute leakage, is rehydrated in the presence of 100 millimolar K⁺, 5 millimolar Mg²⁺, 1 millimolar ATP, and 1 millimolar GTP, either separately or together, there is no stimulation of protein synthesis. When it is hydrated in the presence of either 5 millimolar glucose-6-phosphate or 0.1 millimolar NADPH, protein synthesis is stimulated but the stimulation is transitory. A second addition of either of these two chemicals causes a second transient stimulation of protein synthesis. A transitory decrease in the rate of GSSG accumulation is observed during rehydration in the presence of glucose-6-phosphate or NADPH. Both glucose-6-phosphate and NADPH are known to reverse GSSG-induced inhibition of protein synthesis in rabbit reticulocyte lysate. Results of the present study suggest that the rate of protein synthesis during rehydration of rapidly dried moss is not limited by the availability of ions or energy sources. Since exogenously applied GSSG has been shown to inhibit in vivo and in vitro protein synthesis and since it is known to accumulate during rehydration of rapidly dried, but not slowly dried, moss, it is suggested that the low rate of protein synthesis during rehydration of the rapidly dried moss is, at least in part, due to endogenous GSSG.     

Studies on Protein Synthesis in Tortula ruralis: POLYRIBOSOME REFORMATION FOLLOWING DESICCATION

Desiccation of Tortula ruralis was achieved rapidly by placingthe moss on the laboratory bench, or more slowly by placingit in desiccators with atmospheres of high relative humidities.Unlike the rapidly desiccated moss, the slower desiccated mossretained no polyribosomes in the dehydrated state, althoughpolyribosome reformation and protein synthesis resumed on reintroductionof the moss to water. Protein synthesis commenced on rehydrationof the slower desiccated moss at a greater rate than on rehydrationof the faster desiccated moss. A lack of correlation betweenendogenous ribonuclease activity and polyribosome levels extractedfrom the moss suggests that the observed reduction in polyribosomesduring desiccation was not due to their degradation but wasmore likely a consequence of stress-induced restriction on reinitiationof existing messenger RNA. The observed protein synthesis onrehydration of the moss was largely independent of any priorRNA synthesis.     

Morphological adaptation to water uptake and transport in the poikilohydric moss Tortula ruralis

Abstract

In this paper different water-holding and transport adaptations to face the uneven and intermittent distribution of water in the ectohydric moss Tortula ruralis are referred to.

The external conduction of water is operated by different and efficient systems (spaces between adjacent shoots, between leaves, leaves and stems, leaves and rhizoids, life form, etc.) which facilitate absorption and transport of solutions.

Also epi-organ capillary systems (bases and revoluted margin of leaves, a groove, a close network of capillary channels determined by the papillae), intra-organ capillary systems (hyalocysts) and certain amount of internal conduction (conducting parenchyma, stereoma) co-operante to absorb and distribute water to the whole gametophyte.

In addition, some adaptations to xerophytism and heliophytism (life form, disposition of phylloids, hair-points) are discussed.     

Diurnal variation in photochemical dynamics and surface reflectance of the desiccation-tolerant moss,Tortula ruralis

Most desiccation-tolerant plants alter shoot structure during drying, making it possible to use changes in surface reflectance as a proxy measure of plant water status. Diurnal courses of surface reflectance (albedo) and chlorophyll fluorescence parameters of the ectohydric moss, Tortula ruralis (Hedw.) Gaertn, were measured to assess the coordination between anatomical and physiological features under field conditions. Albedo showed a sigmoidal relationship with relative humidity and the deviation of moss mat temperature from dew point. Maximum photosynthetic quantum yield (F _v/F _m) also displayed a sigmoidal relationship pooled across three days differing in light, temperature, and relative humidity. Depending on the light conditions and rapidity of drying during the morning, there were distinct differences in the ability of T. ruralis to establish thermal dissipation of excess light energy (NPQ) across a range of light levels following rehydration through the day. These findings suggest that there is a coordinated suite of architectural and physiological characteristics maintaining the photosynthetic integrity of these plants in highly variable arid and semi-arid environments.     

Exaggeration of desiccation stress by heavy metal pollution in Tortula ruralis: a pilot study

Glutathione pool and redox status, as well as chlorophyll fluorescencewere measured in Tortula ruralis which was treated withheavy metals and exposed to different desiccation treatments. Two hours afterre-wetting, the ratio of oxidised glutathione to total glutathione poolreturnedto the steady state level (14%) in slowly dried unpolluted plants. Cdtreatment doubled this ratio, as did rapid drying without the heavy metaltreatment. When Cd and rapid drying were applied together, the ratio of GSSGreached 45% indicating a clear additive effect of these two stressfactors. RFd, a chlorophyll fluorescence parameter followed a similar pattern.Lead did not cause the depletion of the glutathione pool but increased theratioof GSSG. It is suggested that Cd and rapid desiccation exert their damageadditively. This might also entail a lowered degree of desiccation tolerance inareas polluted with metals and therefore a retreat of the mosses to mesicmicrohabitats.