Chlorophyll fluorescence as an exploratory tool for ecophysiological studies on mosses and other small poikilohydric plants

Abstract

Photosynthetic pigment content (chlorophylls and carotenoids), slow chlorophyll fluorescence parameters (F_M and F_T at 690 and 735 nm) and net CO₂ assimilation rate were measured in the moss Tortuia ruralis (Hedw.) Gaertn. et al., and the lichens Cladonia convoluta (Lam.) P. Coul. and C. jurcata (Huds.) Schrad.

Chlorophylls, carotenoids and net CO₂ assimilation (P_N) were lower (on a dry-mass basis), and F₆₉₀/F₇₃₅ was higher, in all three cryptogams than average values reported for vascular plants. Within the moss shoots and lichens, chlorophylls, carotenoids, the fluorescence-decrease ratio (Rfd = [F_M–F_T]/F_T) and net photosynthesis (P_N) were higher, and F₆₉₀/F₇₃₅ was lower, in the apical/marginal, younger parts than in the basal, older ones. F₆₉₀/F₇₃₅ was inversely related to chlorophyll a+b, higher values indicating lower chlorophyll content.

There was a good correlation between the Rfd and P_N (measured at optimal water content) in the different parts of the moss and lichens, and in samples of T. ruralis which had been exposed for two months to different levels of atmospheric pollution in a transplant experiment, a correlation also found in published work on the same species in the course of desiccation-remoistening cycles.

Chlorophyll fluorescence provides a non-invasive and relatively quick measure of overall photosynthetic function for ecophysiological studies, using either slow fluorescence kinetics (as here), or measurements from fast or modulated fluorometers.     

The Conservation of Polyribosomes in the Moss Tortula ruralis during Total Desiccation

Total desiccation of the moss Tortula ruralis was achieved byplacing it in a dry atmosphere for 90 min. Reintroduction ofthe moss to water resulted in the recovery of its normal morphologicalform within 15–30 s. The sedimentation profile on a sucrosegradient of the ribosomal content of the totally dry moss showsthe presence of distinct polyribosomal peaks. The levels ofthese polyribosomes rise upon rehydration of the moss. The differencebetween the tolerance to water deficit by this moss and by higherplants is outlined.     

Effects of Intermittent Desiccation on Nutrient Economy and Growth of Two Ecologically Contrasted Mosses

The mossesBrachythecium rutabulum (Hedw.) B., S. & G. andPseudoscleropodiumpurum (Hedw.) Fleisch. were cultivated for more than 50 d ina growth cabinet with or without weekly drying interludes of24 h. Some plants also received applications of a dilute NPKnutrient solution at weekly intervals. The continuously hydratedplants showed appreciably more biomass production than thosereceiving intermittent desiccation. Desiccation led to somebleaching of the green tissues inB. rutabulum but not inP. purumwhich appeared more desiccation-tolerant. NPK addition causeda further significant growth stimulation in continuously hydratedplants, but not in intermittently desiccatedB. rutabulum. Pseudoscleropodiumpurum showed NPK-induced growth stimulation even when intermittentlydesiccated. Net uptake of N was similar in desiccated and hydratedplants in both species. Considerable net uptake of P and K⁺occurredin continuously wetB. rutabulum , but uptake was much reducedin intermittently desiccated plants. Net uptake of P and K⁺byP.purum was similar in desiccated and hydrated samples. IntracellularK⁺, leaked from the cells during the desiccation treatment,was retained by cation exchange on the negatively charged cellwalls in both species. Levels of intracellular K⁺and Mg²⁺inthe new growth were maintained at the expense of the pool ofexchangeable cations. The growth stimulation and the net uptakeof nutrients under intermittent desiccation was greatest whenthe NPK application was made at the start of rehydration, possiblybecause of accentuated uptake in the early stages of recovery.The results support the hypothesis thatP. purum has a lowernutrient requirement thanB. rutabulum and highlight the importanceof continuous hydration for the latter's more productive plantlife strategy. The data also show that considerable new growthof bryophyte tissues is possible without additional nutrientabsorption. Brachythecium rutabulum ; Pseudoscleropodium purum ; mineral nutrition; desiccation; solute leakage; plant life strategies     

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.     

Water Stress and Protein Synthesis: V. Protein Synthesis, Protein Stability, and Membrane Permeability in a Drought-sensitive and a Drought-tolerant Moss

The effects have been studied of water stress and desiccation on protein synthesis in the drought-tolerant moss Tortula ruralis and the drought-sensitive moss Hygrohypnum luridum. At any particular level of steady state water stress, the inhibition of protein synthesis was greater in H. luridum than in T. ruralis. Water stress-induced changes in the pattern of protein synthesis, as determined by the double label ratio technique, were minor in T. ruralis, but major in H. luridum. Proteins of both mosses were found to be stable during desiccation and subsequent rehydration. Changes in membrane permeability, as indicated by the leakage of amino acid, were observed during rehydration of desiccated moss and were dependent on the rate of desiccation. The leakage was small and reversible in T. ruralis but large and irreversible in H. luridum. Although H. luridum failed to recover from complete desiccation (80% loss in fresh weight), it was able to recover fully from steady state stress under conditions where a maximum loss of 55% in fresh weight was recorded.     

Respiration in Relation to Adenosine Triphosphate Content during Desiccation and Rehydration of a Desiccation-tolerant and a Desiccation-intolerant Moss

O₂ consumption by the desiccation-tolerant moss Tortula ruralis and the desiccation-intolerant Cratoneuron filicinum increased markedly during the latter stages of desiccation. ATP content of the mosses during desiccation was not correlated with O₂ consumption, but was influenced by the rate at which the mosses lost water. The more rapid the water loss, the more ATP that was present in the dry mosses. The pattern of O₂ consumption on rehydration also was influenced by the previous rate of desiccation. After rapid desiccation of T. ruralis O₂ consumption upon rehydration was considerably elevated, and for up to 24 hours. After very slow desiccation the elevation was small and brief. Normal O₂ consumption did not occur in C. filicinum after rapid desiccation, but did so within a few hours of rehydration after slower speeds of drying. ATP levels in T. ruralis returned to normal within 5 to 10 minutes of rehydration. In C. filicinum, increases in ATP were closely correlated with O₂ consumption. These observations are considered to be related to differential damage caused to mitochondria and to cellular integrity by different speeds of water loss. The desiccation-tolerant moss appears to be able to repair the severe damage imposed by rapid desiccation whereas the desiccation-intolerant moss cannot.     

Plant desiccation and protein synthesis: an in vitro system from dry and hydrated mosses using endogenous and synthetic messenger ribonucleic Acid

The conditions and requirements for an in vitro protein synthesizing system from the moss Tortula ruralis are outlined. Using this system the effects of desiccation, achieved quickly or slowly, were studied. Slowly dried moss retained fewer polyribosomes on desiccation but more active ribosomes than rapidly dried moss. Even in the completely desiccated moss the polyribosomes and/or free ribosomes present have retained their synthetic capacities. On rehydration, the slowly dried moss resumed protein synthesis more quickly than moss previously desiccated rapidly. Moss ribosomes are cycloheximide sensitive and chloramphenicol insensitive and thus the major protein synthesis occurs within the cytoplasm on rehydration. Extracted polyribosomes per se can withstand desiccation to a significant extent, suggesting that protection by the cytoplasm might not be necessary. The aquatic moss Hygrohypnum luridum can retain polyribosomal and ribosomal activity during desiccation, but this decreases greatly on rehydration.     

Nutrient retention by Pseudoscleropodium purum and its relation to growth

Abstract

A complete mineral nutrient fertilizer solution was added to carpets of Pseudoseleropodium purum growing in Windsor Forest, Berkshire, to study the efficiency of nutrient capture from dilute solutions and its effect on growth. In the experiment different frequencies of application were balanced by employing different concentrations of fertilizer so that all treatment plots received the same quantities of nutrients over a six-month period. At the end of the experiment the concentrations of macronutrients (N, P, K, Mg, Ca) within the moss tissues were determined and shoot growth was assessed by the tagged shoot method.

Significant luxury uptake occurred only in the case of P where shoot concentrations in fertilized plots were 50% above the control. Smaller net increases were noted for other elements, particularly Mg. Shoot N concentration was hardly affected by fertilizer application possibly due to efficient internal recycling of the element in P. purum. Levels of exchange ably held cations were not markedly increased by fertilizer addition in the field experiment but when shoots were incubated with fertilizers in the laboratory for 30 min the concentrations of exchangeable Ca and Mg rose appreciably and exchangeable K fell. These changes appear to be quickly reversed under field conditions without transfer of cations to the protoplasts. The importance of elevated cation exchange capacity in the initial sequestration of nutrient cations is, therefore, questioned. Growth stimulation due to fertilizer treatment was negligible. Maximum net uptake of P, Mg and Ca occurred when plots were watered at weekly intervals with a dilute fertilizer and least occurred where a concentrated solution was applied at less frequent intervals implying that contact time between P. purum and its potential nutrients is an important factor. The period elapsing between fertilizer additions may also have significance, however, due to leaching away of nutrients and the re-establishment of a natural ionic balance at the cell wall exchange sites. Levels of nutrient absorption and growth were greatest at a site where the moss remained moist longest. This result indicates that the ability of P. purum to absorb and utilize additional nutrients is governed by general metabolic performance which is itself restricted by water supply in Windsor Forest.     

Alternate Bearing Affects Nitrogen, Phosphorus, Potassium and Starch Storage Pools in Mature Pistachio Trees

The relationship between crop load and the functional storageof selected macronutrients and starch was assessed to developnutrient budgets and best management fertilization practicesin orchards. Functional storage represents the amount of nutrientsand starch redistributed from perennial tree parts in supportof the spring growth flush. Functional storage was influencedby:(a)nutrient and starch accumulation prior to dormancy; and(b)nutrientand starch demand by vegetative and reproductive organs in spring.Lightly cropping (off-year) trees stored 7, 14 and 2 times asmuch N, P and K, respectively, as heavily cropping (on-year)trees. Similar to many biennial plant species, nutrients thataccumulated during the vegetative phase in off-year trees wereused to support reproductive growth during the subsequent on-year.Soil nutrient uptake contributed more to storage pools thanleaf nutrient resorption in off-year-trees, while the reversewas true in on-year trees. Net nutrient resorption from senescingleaves accounted for all of the N and P and a third of the Kstored in on-year trees. Only between 20–33% of the N,P and K stored in perennial tissues of off-year trees couldbe attributed to leaf nutrient resorption. This is the firststudy to determine the amounts of nutrients stored in the perennialparts of mature, field-grown trees and the relative contributionsof leaf nutrient resorption and soil nutrient uptake to functionalstorage in trees.Copyright 1998 Annals of Botany Company Pistacia vera, nutrient storage, biennial bearing, crop load, leaf nutrient resorption, source-sink relationships.     

Mineral Nutrition of Sandalwood (Santalum spicatum)

Acacia acuminata is a preferred host of the root hemiparasitictree, Santalum spicatum (sandalwood). Comparison between nutrientcontent of adult trees of sandalwood and results for an earlierstudy of the mistletoe, Amyema preissii, on the same host species,A. acuminata, showed similar high levels of K and Na and lowlevels of Zn in both parasites compared with the host plants.Differences in K, Ca, N and Cu levels between parasitized anduninfected Acacias imply that the host plant contributes tothe nutrition of sandalwood. The high K/Ca ratio in sandalwoodconfirms that K uptake in preference to Ca is a general featureof all categories of angiosperm parasites. Patterns of distribution of nutrients between various partsof sandalwood and A. acuminata depend on the type of nutrient,but levels are usually highest in leaves of both species andthe haustoria. Although K, Ca and Na are much lower in the kernelsthan in vegetative parts of the parasite, only seedlings withoutsupplementary Ca in a nutrient omission experiment failed togrow at all in the absence of hosts. Growth is not dependenton the level of K in the unattached plants but other evidenceindicates it may have a role in water uptake in the attachedplant. Calcium supply has a marked effect on internal Ca levelsand growth of unattached plants. Compared with field plants,levels of Ca, and to a lesser extent Zn, were much higher inplants of the Ca/K treatment that produced greatest growth over34 weeks. Haustorial formation is enhanced by the presence of A. acuminataroots. However, competition for nutrients, especially Ca, fromco-planted A. acuminata seedlings results in suppression ofgrowth of young sandalwood compared with their growth in theabsence of the host species. Key words: Mineral nutrients, Santalum spicatum, Acacia acuminata, hemiparasites, K/Ca nutrition, seeds     

Filling the interspace—restoring arid land mosses: source populations,organic matter,and overwintering govern success

Biological soil crusts contribute to ecosystem functions and occupy space that could be available to invasive annual grasses. Given disturbances in the semiarid shrub steppe communities, we embarked on a set of studies to investigate restoration potential of mosses in sagebrush steppe ecosystems. We examined establishment and growth of two moss species common to the Great Basin, USA: Bryum argenteum and Syntrichia ruralis from two environmental settings (warm dry vs. cool moist). Moss fragments were inoculated into a third warm dry setting, on bare soil in spring and fall, both with and without a jute net and with and without spring irrigation. Moss cover was monitored in spring seasons of three consecutive years. Both moss species increased in cover over the winter. When Bryum received spring irrigation that was out of sync with natural precipitation patterns, moss cover increased and then crashed, taking two seasons to recover. Syntrichia did not respond to the irrigation treatment. The addition of jute net increased moss cover under all conditions, except Syntrichia following fall inoculation, which required a second winter to increase in cover. The warm dry population of Bryum combined with jute achieved on average 60% cover compared to the cool moist population that achieved only 28% cover by the end of the study. Differences were less pronounced for Syntrichia where moss from the warm dry population with jute achieved on average 51% cover compared to the cool moist population that achieved 43% cover by the end of the study. Restoration of arid land mosses may quickly protect soils from erosion while occupying sites before invasive plants. We show that higher moss cover will be achieved quickly with the addition of organic matter and when moss fragments originate from sites with a climate that is similar to that of the restoration site.     

ABA Increases the Desiccation Tolerance of Photosynthesis in the Afromontane Understorey Moss Atrichum androgynum

The effect of pretreatment with abscisic acid (ABA) on the physiologyof the moss Atrichum androgynum during a desiccation–rehydrationcycle was examined. During rehydration following desiccationfor 16 h, net CO₂fixation recovered much more slowly than photosystemII (PSII) activity, conditions conducive to the formation ofreactive oxygen species (ROS) in the photosynthetic apparatus.Pretreatment with ABA increased the rate of recovery of photosynthesisand PSII activity, and also doubled non-photochemical quenching(NPQ). Increased NPQ activity will reduce ROS formation, andmay explain in part how ABA hardens the moss to desiccation.In ABA-pretreated, but not untreated mosses, desiccation significantlyincreased the concentration of soluble sugars. Sugar accumulationmay promote vitrification of the cytoplasm and protect membranesduring desiccation. Starch concentrations in freshly collectedA. androgynum were only approx. 40 mg g^-1dry mass; they roseslightly during desiccation but were only slightly affectedby ABA pretreatment. ABA did not reduce chlorophyll breakdownduring desiccation. Copyright 2001 Annals of Botany Company Moss, desiccation, abscisic acid, photosynthesis, chlorophyll fluorescence     

Drought Tolerance in Two Mosses: Correlated with Enzymatic Defence Against Lipid Peroxidation

Drought-induced changes in the activities of superoxide dismutase(SOD) and catalase, level of lipid peroxidation, and membranepermeability (solute leakage) have been studied in two mosses,the drought-tolerant Tortula ruralis and the drought-sensitiveCratoneuron filicinum. In T. ruralis the activities of SOD andcatalase increase during slow drying. The level of lipid peroxidationconsequently declines. On subsequent rehydration the enzymeactivities decline and the level of lipid peroxidation risesgradually to normal levels. The leakage of preloaded ⁸⁶Rb onrehydration of slowly dried T. ruralis is similar to that inturgid moss, i.e. leakage of about 20% of tissue ⁸⁶Rb. WhenT. ruralis is subjected to rapid drying there is no change inthe enzyme activities or in lipid peroxidation. However, whenthis moss is rehydrated there is a large immediate increasein lipid peroxidation. Half of the tissue ⁸⁶Rb is leaked intothe bathing medium during the first hour of rehydration. Butwithin the next hour, when SOD and catalase activities haveincreased to high levels, lipid peroxidation quickly declinesto a level lower than that in the turgid control moss, and the⁸⁶Rb leaked earlier is partly reabsorbed indicating that membranerepair is well underway. On prolonged rehydration the enzymeactivities decline and the level of lipid peroxidation risesgradually to reach normal levels found in control turgid moss.In the case of drought-sensitive C. filicinum the activitiesof SOD and catalase decline during drying as well as duringsubsequent rehydration. There is a rapid increase in lipid peroxidationduring rehydration and most of the preloaded ⁸⁶Rb leaks intothe bathing medium irreversibly. The changes in lipid peroxidationduring drying and subsequent rehydration of both the mossesappear to coincide in time with the reported changes in O₂ uptake,indicating that the drought-induced membrane damage may be dueto free radical-induced lipid peroxidation which is known torequire active O₂ uptake. Furthermore, there appears to be agood correlation between an ability of the tissue to controllipid peroxidation and its ability to retain solutes. It issuggested that ability of plant tissues to mobilize enzymaticdefence against uncontrolled lipid peroxidation may be an importantfacet of their drought tolerance.     

Stability and Synthesis of Phospholipids during Desiccation and Rehydration of a Desiccation-Tolerant and a Desiccation-Intolerant Moss

The fatty acid composition of the phospholipids from the desiccation-tolerant moss Tortula ruralis (Hedw.) Gaertn, Meyer and Scherb and the desiccation-intolerant moss Cratoneuron filicinum has been determined. No changes in composition occur in either moss as a consequence of rapid drying, but, after slow drying, there is a decline in some unsaturated fatty acids. Upon rehydration of T. ruralis after slow drying, these acids decline further; however, within 105 minutes, they regain the same levels as those in undesiccated controls. A smaller and more transient decline occurs after rapid desiccation. Most phospholipid unsaturated fatty acids decrease during rehydration of C. filicinum, and their levels are not recovered. After both rapid and slow drying of T. ruralis, acetate and glycerol are incorporated into the phospholipid fraction, although de novo synthesis, alone, might not account for the increase in unsaturated fatty acids upon rehydration. Very little acetate or glycerol is incorporated during rehydration of C. filicinum. Loss of unsaturated fatty acids from the phospholipids of T. ruralis does not appear to be associated with increased lipoxygenase activity. Furthermore, there is little correlation between the extent of peroxidation of fatty acids due to desiccation and changes in the phospholipid fraction.     

Nutrient Supply, Dry-matter Production and Nutrient Uptake of Forest Tree Seedlings

The dry-matter production and nutrient uptake of forest-treeseedlings grown under controlled levels of nutrition in sub-irrigatedsand culture were investigated. Hardwood seedlings attainedgreater dry weight than conifer seedlings, and Pinus radiataa greater dry weight than P. contorta and P. nigra, but thesegreater dry weights were not related to greater leaf/weightratios, although seed size may have been an important influenceon final seedling dry weight. P. radiata was found to have alower requirement for P than P. contorta and P. nigra in oneexperiment. The demand (total nutrient uptake per unit of time) made bythree species for nutrients upon a site was shown to dependmore upon growth-rate per annum than on efficiency (quantityof nutrients required to produce a unit of dry matter). It isconcluded that the ability of tree species to grow satisfactorilyon soils of low nutrient status depends largely on their abilityfor relatively slow growth. On the other hand, species showinggood response to favourable sites may also make satisfactorygrowth on poor sites.     

Resolving neutral and deterministic contributions to genomic structure in <Emphasis Type="Italic">Syntrichia ruralis</Emphasis> (Bryophyta,Pottiaceae) informs propagule sourcing for dryland restoration

Syntrichia ruralis is a cosmopolitan moss that occupies steep environmental gradients. In arid to semi-arid regions of the world it is a key component of biological soil crusts, which are fundamental to healthy dryland ecosystem processes. As such, S. ruralis has attracted the attention of conservationists seeking to restore degraded biological soil crust communities and their associated vascular flora. Here, we generate genomic data for S. ruralis populations that span climatic gradients across the Colorado Plateau of the southwestern USA to investigate the contributions of neutral and deterministic processes to the partitioning of genomic structure. Although S. ruralis appears to be highly dispersible, geographic proximity significantly predicts genomic similarity. In addition, even when taking into account apparently high migration rates among populations and spatial autocorrelation of allele frequencies, some genomic variation is explained by environmental gradients correlated with elevation and latitude. Consequently, efforts to restore dryland ecosystems by establishing S. ruralis as a foundation should include strategies to ensure that propagule sources of this moss are environmentally stratified and targeted to the current/future climates of restoration sites.     

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.     

Structure and Function of an Age Series of Eucalypt Plantations in Central Himalaya, II. Nutrient Dynamics

This paper deals with nutrient dynamics in 2- to 8-year-oldplantations of Eucalyptus tereticornis Sm. previously investigatedfor dry matter dynamics. The nutrient concentrations changedin the order: herb > shrub > tree. The nutrient concentrationsin the different components of these vegetation types also decreasedwith plantation age. The nutrient content in trees and shrubsincreased and in herbs it decreased with increase in plantationage. The uptake of nutrients by vegetation and also by componentswith or without adjustment for retranslocation, has been calculatedseparately. Turnover time for different nutrients ranged between1.05 and 1.35 years. Compartmental models for nutrient dynamicshave been developed to represent the distribution of nutrientcontents and net annual fluxes within the system. Eucalyptus tereticornis plantation, nutrient concentration, standing state, uptake, turnover, nutrient cycling     

Structure and Function of an Age Series of Poplar Plantations in Central Himalaya. II Nutrient Dynamics

This paper elucidates nutrient dynamics in 5- to 8-year-oldpoplar (Populus deltoides) clone D₁₂₁ plantations previouslyinvestigated for dry matter dynamics. The nutrient concentrationin different layers of the vegetation were in the order: tree> shrub > herb, whereas the standing state of nutrientswere in the order: tree > herb > shrub. Soil, litter andvegetation, respectively, accounted for 80-89, 2-3 and 9-16%of the total nutrients in the system. Considerable reductions(trees 42-54, shrubs 31-37 and herbs 15-23%) in concentrationof nutrients in leaves occurred during senescence. The uptakeof nutrients by the vegetation and also by the different components,with and without adjustment for internal recycling, has beencalculated separately. Annual transfer of litter nutrient tothe soil by vegetation was 113·7-137·6 N, 11·6-14·6P and 80·1-83·2 K kg ha^-1 year^-1. Turnover rateand time for different nutrients ranged between 0·72-0·89year^-1 and 1·12-1·39 years, respectively. Thehigh turnover rate of litter on the forest floor indicates thegreater productivity of the stands, which was due to the higherdry matter dynamics and nutrient release for the growing vegetation.The nutrient use efficiency in poplar plantations ranged from159-175 for N, 1405-1569 for P and 295-332 for K. Compared withEucalyptus, there was a higher proportion of nutrient retranslocationin poplars largely because of higher tissue nutrient concentrations;this indicates lower nutrient use efficiency as compared tothe eucalypt plantation. Compartment models for nutrient dynamicshave been developed to represent the distribution of nutrientpools and net annual fluxes within the system.Copyright 1995,1999 Academic Press Populus deltoides plantations (Clone D₁₂₁), nutrient retranslocation, net nutrient uptake, nutrient use efficiency, nutrient cycling, nutrient pool, nutrient fluxes