Characterization of Phloem iron and its possible role in the regulation of fe-efficiency reactions

`Fe-efficiency reactions' are induced in the roots of dicotyledonous plants as a response to Fe deficiency. The role of phloem Fe in the regulation of these reactions was investigated. Iron travels in the phloem of Ricinus communis L. as a complex with an estimated molecular weight of 2400, as determined by gel exclusion chromatography. The complex is predominantly in the ferric form, but because of the presence of reducing compounds in the phloem sap, there must be a fast turnover in situ between ferric and ferrous (k ≈ 1 min⁻¹). Iron concentrations in R. communis phloem were determined colorimetrically or after addition of ⁵⁹Fe to the nutrient solution. The iron content of the phloem in Fe-deficient plants was lower (7 micromolar) than in Fe-sufficient plants (20 micromolar). Administration of Fe-EDTA to leaves of Phaseolus vulgaris L. increased the iron content of the roots within 2 days, and decreased proton extrusion and ferric chelate reduction. The increase in iron content of the roots was about the same as the difference between iron contents of roots grown on two iron levels with a concomitantly different expression of Fe-efficiency reactions. We conclude that the iron content of the leaves is reflected by the iron content of the phloem sap, and that the capacity of the phloem to carry iron to the roots is sufficient to influence the development of Fe-efficiency reactions. This does not preclude other ways for the shoot to influence these reactions.     

Humic acid and iron uptake by plants

Summary The behaviour of ferric EDTA and ferric citrate in nutrient solution and their interaction with humic acid was investigated at various hydrogen ion concentrations using the technique of membrane ultrafiltration to separate small iron species from high molecular weight products of hydrolysis and to estimate the binding of iron by humic acid. Ferric EDTA was found to be of small molecular size at all pH values between 5.0 and 7.0 whilst ferric citrate solutions contained an increasing proportion of high molecular weight material as pH was increased from 5.0 to 7.0. Some iron present in solutions of both ferric EDTA and ferric citrate was bound by humic acid at all pH values from 5.0 to 7.0. Studies were also made of the uptake of iron by wheat roots from nutrient solutions containing either ferric EDTA or ferric citrate and of the effect of humic acid on uptake. More iron was absorbed from ferric EDTA than from ferric citrate at all pH values. Increasing pH between 5.0 and 7.0 resulted in a progressive decrease in the uptake of iron in both cases. The presence of humic acid depressed iron absorption from both solutions at all pH values.     

Nicotianamine: mediator of transport of iron and heavy metals in the phloem?

Recent work has demonstrated that minerals in plants are circulated between root and shoot. This occurs during the whole life time and renders possible response to changing environmental conditions. This mineral circulation occurs through intensive solute exchange between xylem and phloem in roots, stems, and leaves. The transport form of heavy metals such as iron, manganes, zinc and copper in the phloem, whether ionic or chelated, is unclear in most cases.
The unusual amino acid nicotianamine (NA) is ubiquitous throughout the plant kingdom. It is a chelator of several divalent transition metals. Its physiological role was investigated with the tomato mutant chloronerva, the only known NA-free multicellular plant. The mutant also exhibits disturbances of its iron metabolism and that of other heavy metals. This leads, among others, to a typical intercostal chlorosis and progressive iron accumulation in the leaves. From the heavy metal chelating properties of NA and from the phenotype of the mutant chloronerva it is concluded that NA is needed for normal distribution of heavy metals in young growing tissues fed via the phloem. This function could be fulfilled by mediating phloem loading or unloading of heavy metals as well as by preventing their precipitation in the alkaline phloem sap. An attempt is made to explain the chloronerva phenotype in the light of the phloem transport hypothesis of chelated iron.     

High resolution structure of an alternate form of the ferric ion binding protein from Haemophilus influenzae

The periplasmic iron binding protein of pathogenic Gram-negative bacteria performs an essential role in iron acquisition from transferrin and other iron sources. Structural analysis of this protein from Haemophilus influenzae identified four amino acids that ligand the bound iron: His(9), Glu(57), Tyr(195), and Tyr(196). A phosphate provides an additional ligand, and the presence of a water molecule is required to complete the octahedral geometry for stable iron binding. We report the 1.14-A resolution crystal structure of the iron-loaded form of the H. influenzae periplasmic ferric ion binding protein (FbpA) mutant H9Q. This protein was produced in the periplasm of Escherichia coli and, after purification and conversion to the apo form, was iron-loaded. H9Q is able to bind ferric iron in an open conformation. A surprising finding in the present high resolution structure is the presence of EDTA located at the previously determined anion ternary binding site, where phosphate is located in the wild type holo and apo structures. EDTA contributes four of the six coordinating ligands for iron, with two Tyr residues, 195 and 196, completing the coordination. This is the first example of a metal binding protein with a bound metal.EDTA complex. The results suggest that FbpA may have the ability to bind and transport iron bound to biological chelators, in addition to bare ferric iron.     

Sensing Iron--A Whole Plant Approach

Regulatory mechanisms leading to cellular Fe homeostasis wereinvestigated inPlantago (Plantago lanceolata L.) plants grownhydroponically at different temperature regimes either in thepresence or absence of iron. During the experimental periodof 6 d, growth was not affected by Fe availability, but wasdecreased by lowering the root zone temperature (RZT) from 24to 12°C. Cultivating plants at low RZT decreased the reductionactivity for ferric chelates in Fe-deficient plants. In thepresence of iron, the temperature regime did not affect Fe accumulationby root cells, but decreased translocation of Fe to the shoot,and chlorosis of young leaves was observed at suboptimal RZT.Under these conditions root-mediated reduction of ferric chelateswas increased. In cold-treated plants this effect was specificto Fe and could not be evoked by Mn²⁺and Zn ^{+ 2}additions. Supplementingthe medium with the ferrous scavenger ferrozine caused a furtherenhancement in reduction rates, probably due to mobilizationof apoplastic Fe. These results can be explained plausibly ifdifferent sites of Fe sensing are postulated and if it is assumedthat both the absence and presence of iron could be a signalincreasing root reduction activity. Copyright 2000 Annals ofBotany Company Adaptation, iron uptake regulation, ferric reduction, Plantago lanceolata, root zone temperature, whole plant signalling     

Reduction of ferric iron by acidophilic heterotrophic bacteria: evidence for constitutive and inducible enzyme systems in Acidiphilium spp

AIMS: To compare the abilities of two obligately acidophilic heterotrophic bacteria, Acidiphilium acidophilum and Acidiphilium SJH, to reduce ferric iron to ferrous when grown under different culture conditions. METHODS AND RESULTS: Bacteria were grown in batch culture, under different aeration status, and in the presence of either ferrous or ferric iron. The specific rates of ferric iron reduction by fermenter-grown Acidiphilium SJH were unaffected by dissolved oxygen (DO) concentrations, while iron reduction by A. acidophilum was highly dependent on DO concentrations in the growth media. The ionic form of iron present (ferrous or ferric) had a minimal effect on the abilities of harvested cells to reduce ferric iron. Whole cell protein profiles of Acidiphilium SJH were very similar, regardless of the DO status of the growth medium, while additional proteins were present in A. acidophilum grown microaerobically compared with aerobically-grown cells. CONCLUSIONS: The dissimilatory reduction of ferric iron is constitutive in Acidiphilium SJH while it is inducible in A. acidophilum. SIGNIFICANCE AND IMPACT OF THE STUDY: Ferric iron reduction by Acidiphilium spp. may occur in oxygen-containing as well as anoxic acidic environments. This will detract from the effectiveness of bioremediation systems where removal of iron from polluted waters is mediated via oxidation and precipitation of the metal.     

Effects of iron sources on the growth and lipid/carbohydrate production of marine microalga <Emphasis Type="Italic">Dunaliella tertiolecta</Emphasis>

The effects of iron sources with different speciation and anionic moieties (ferric chloride, ferrous chloride, ferric EDTA, ferrous EDTA, ferric ammonium sulfate, and ferrous ammonium sulfate) on the cell growth and the production of energy storage (lipid and carbohydrate) from Dunaliella tertiolecta were investigated. The influence of iron dosage was also compared in the range from 0.65 mg/L (1X) to 6.5 mg/L (10X) as Fe concentration. Best cell growth rate was achieved when ferrous ammonium sulfate was used. Ferric EDTA resulted in higher lipid content than other iron sources, while ferrous ammonium sulfate favored the accumulation of carbohydrate among six iron sources. The accumulations of lipid and carbohydrate as energy storage competed each other and thus both contents did not increase together. In the presence of ferric EDTA, lipid content is increasing, while carbohydrate content is decreasing. On the contrary, lipid content is decreasing while carbohydrate is increasing in the presence of ferric ammonium sulfate. Because the overall carbohydrate content was larger than that of lipid, bioethanol production would be more advantageous than biodiesel production with the present D. tertiolecta strain if the carbohydrate in D. tertiolecta contains a high fraction of glucose with a good saccharification yield.     

Different iron sources to study the physiology and biochemistry of iron metabolism in marine micro-algae

We compared ferric EDTA, ferric citrate and ferrous ascorbate as iron sources to study iron metabolism in Ostreococcus tauri, Phaeodactlylum tricornutum and Emiliania huxleyi. Ferric EDTA was a better iron source than ferric citrate for growth and chlorophyll levels. Direct and indirect experiments showed that iron was much more available to the cells when provided as ferric citrate as compared to ferric EDTA. As a consequence, growth media with iron concentration in the range 1–100 nM were rapidly iron-depleted when ferric citrate—but not ferric EDTA was the iron source. When cultured together, P. tricornutum cells overgrew the two other species in iron-sufficient conditions, but E. huxleyi was able to compete other species in iron-deficient conditions, and when iron was provided as ferric citrate instead of ferric EDTA, which points out the critical influence of the chemical form of iron on the blooms of some phytoplankton species. The use of ferric citrate and ferrous ascorbate allowed us to unravel a kind of regulation of iron uptake that was dependent on the day/night cycles and to evidence independent uptake systems for ferrous and ferric iron, which can be regulated independently and be copper-dependent or independent. The same iron sources also allowed one to identify molecular components involved in iron uptake and storage in marine micro-algae. Characterizing the mechanisms of iron metabolism in the phytoplankton constitutes a big challenge; we show here that the use of iron sources more readily available to the cells than ferric EDTA is critical for this task.     

Ferric iron and superoxide ions are required for the killing of cultured hepatocytes by hydrogen peroxide. Evidence for the participation of hydroxyl radicals formed by an iron-catalyzed Haber-Weiss reaction

Cultured hepatocytes pretreated with the ferric iron chelator deferoxamine were resistant to the toxicity of H2O2 generated by either glucose oxidase or by the metabolism of menadione (2-methyl-1,4-naphthoquinone). Ferric, ferrous, or cupric ions restored the sensitivity of the cells to H2O2. Deferoxamine added to hepatocytes previously treated with this chelator prevented the restoration of cell killing by only ferric iron. The free radical scavengers mannitol, thiourea, benzoate, and 4-methylmercapto-2-oxobutyrate protected either native cells exposed to H2O2 or pretreated hepatocytes exposed to H2O2 and given ferric or ferrous iron. Superoxide dismutase prevented the killing of native hepatocytes by either glucose oxidase or menadione. With deferoxamine-pretreated hepatocytes, superoxide dismutase prevented the cell killing dependent upon the addition of ferric but not ferrous iron. Catalase prevented the killing by menadione of deferoxamine-pretreated hepatocytes given either ferric or ferrous iron. Deferoxamine pretreatment did not prevent the toxicity of t-butyl hydroperoxide but did, however, prevent that of cumene hydroperoxide. It is concluded that both ferric iron and superoxide ions are required for the killing of cultured hepatocytes by H2O2. The toxicity of H2O2 is also dependent upon its reaction with ferrous iron to form hydroxyl radicals by the Fenton reaction. The ferrous iron needed for this reaction is formed by the reduction of cellular ferric iron by superoxide ions. Such a sequence corresponds to the so-called iron-catalyzed Haber-Weiss reaction, and the present report documents its participation in the killing of intact hepatocytes by H2O2. Cumene hydroperoxide but not t-butyl hydroperoxide closely models the toxicity of hydrogen peroxide.     

The Uptake and Flow of C, N and lons between Roots and Shoots in Ricinus communis L.

Seedlings of Ricinus communis L. cultivated in quartz sand weresupplied with a nutrient solution containing either 1 mol m^–3NO^–₃ or 1 mol m^–3 NH⁺₄ as the nitrogen source. Duringthe period between 41 and 51 d after sowing, the flows of N,C and inorganic ions between root and shoot were modelled andexpressed on a fresh weight basis. Plant growth was clearlyinhibited in the presence of NH⁺₄. In the xylem sap the majornitrogenous solutes were nitrate (74%) or glutamine (78%) innitrate or ammonium-fed plants, respectively. The pattern ofamino acids was not markedly influenced by nitrogen nutrition;glutamine was the dominant compound in both cases. NH⁺₄ wasnot transported in significant amounts in both treatments. Inthe phloem, nitrogen was transported almost exclusively in organicform, glutamine being the dominant nitrogenous solute, but theN-source affected the amino acids transported. Uptake of nitrogenand carbon per unit fresh weight was only slightly decreasedby ammonium. The partitioning of nitrogen was independent ofthe form of N-nutrition, although the flow of nitrogen and carbonin the phloem was enhanced in ammonium-fed plants. Cation uptakerates were halved in the presence of ammonium and lower quantitiesof K⁺, Na⁺ and Ca²⁺ but not of Mg²⁺ were transported to theshoot. As NH⁺₄ was balanced by a 30-fold increase in chloride in thesolution, chloride uptake was increased 6-fold under ammoniumnutrition. We concluded that ammonium was predominantly assimilated inthe root. Nitrate reduction and assimilation occurred in bothshoot and root. The assimilation of ammonium in roots of ammonium-fedplants was associated with a higher respiration rate. Key words: Ricinus communis, nitrogen nutrition (nitrate/ammonium), phloem, xylem, transport, partitioning, nitrogen, carbon, potassium, sodium, magnesium, calcium, chloride     

Regulatory role of iron and EDTA in the shoot development from the epicotyl explants of Syzygium cuminii

Iron has proved to be an integral component of the culture medium supporting the caulogenic response of the epicotyl segments of S. cuminii. In the absence of both the iron and EDTA even the shoot buds failed to develop, while in the presence of either of these, though the shoot buds developed, their elongation was adversely affected. Among the three iron sources tested, ferrous sulphate proved to be the best, as the ferric chloride was not as effective as the former when used either alone or along with EDTA. Ferric citrate, on the other hand, when provided alone, elicited better response than that induced by ferrous sulphate alone. However, in combination with EDTA, the response declined significantly. The estimation of endogenous levels of iron in the explants further supported these results. The quantum of iron absorption was at a maximum during the first week of the culture and the explants, once deprived of iron during the first week, failed to catch up to the level of iron accumulated in the explants maintained continuously on complete medium, even after transfer to the complete medium. Likewise, the level of copper ions did not come up to comparable levels even if the explants were transferred to the complete medium after initial deprivation.     

Effects of porphyrins and inorganic iron on the growth of Prevotella intermedia

We demonstrated earlier that hemin-iron-containing compounds which include hemin, human hemoglobin, bovine hemoglobin, and bovine catalase stimulate the growth of Prevotella intermedia [Leung, Subramaniam, Okamoto, Fukushima, Lai, FEMS Microbiol. Lett. 162 (1998) 227-233]. However, the contributions of tetrapyrrole porphyrin ring in these hemin-iron sources as well as inorganic iron for the growth of this organism have not been determined. The purpose of this study was to examine the effects of porphyrins, host iron-binding proteins, and various inorganic iron sources on the growth of hemin-iron depleted P. intermedia. Protoporphyrin IX and protoporphyrin IX-zinc, either in the presence or absence of supplemented ferrous or ferric iron, promoted the growth of P. intermedia at a rate that was comparable to that of the hemin control. On the other hand, neither the host iron proteins, transferrin and lactoferrin, nor the inorganic iron sources which included ferrous chloride, ferric chloride, ferric citrate, ferric nitrate, and ferric ammonium citrate at concentrations up to 200 microM stimulated the growth of hemin-iron-restricted P. intermedia. The results suggest that P. intermedia only use iron in a specific form and that the porphyrin-ring structure is essential for the growth of P. intermedia as in the case of other related organisms.     

Effects of cadmium and lead on ferric chelate reductase activities in sugar beet roots

The effects of the heavy metals Cd and Pb on the activity of the enzyme ferric chelate reductase (FC-R, E.C. 1.6.99.13) have been studied in excised sugar beet root tips. The activity of this enzyme is markedly increased by iron deficiency. Metals were used as chloride salts or chelated with EDTA, and chemical speciation was carried out to predict the metal chemical species in equilibrium both in the ferric reductase assay and in the nutrient solutions. Three different heavy metal treatments were used. First, effects of Cd and Pb on the functioning of the FC-R were assessed in Fe-deficient plants, by including metals in the enzyme assay medium only. Results indicate that 50 μM CdCl₂ or Cd-EDTA did not affect FC-R activities even when assay time was as long as 2 h, whereas Pb slightly decreased enzyme activity only at concentrations of 2 mM. Second, short-time Cd and Pb pre-treatments (30–60 min) were imposed on intact Fe-deficient plants before carrying out the assay of FC-R activity. These short-term treatments induced significant decreases in the FC-R activities previously induced by Fe deficiency. With Cd, effects were more pronounced at higher concentrations, and they were stronger when Cd was in the free ion form than when present in the form of Cd-EDTA chelate. Third, prolonged Cd and Pb treatments were imposed on plants grown on 45 μM Fe-EDTA to assess the long-term effects of heavy metals on the induction of the FC-R enzyme. These long-term heavy metal treatments caused a significant increase in the root FC-R activities, indicating that Cd and Pb induce a deficiency in Fe in sugar beet that in turn elicits FC-R activity. The increases, however, are not as large as those found in total absence of Fe.     

TOXIC EFFECTS OF HEAVY METALS ON CROP PLANTS GROWN IN SOIL CULTURE

A number of pot experiments were made on various crops, to study the effects on the chemical composition of the plants of treating the soil with cobalt, copper or nickel sulphates, or with the cupric or ferric salts of ethylenediamine-tetraacetic acid (EDTA).
The tops of copper sulphate-treated plants usually contained higher concentrations of copper, manganese, calcium and magnesium and lower concentrations of potassium and phosphorus, than those of control plants.
The most marked effect of cobalt on oat was to increase the concentration of Ca+Mg in the tops; nickel had a profound effect on the composition of barley tops.
Total iron concentration was reduced in oat by cobalt and copper, and in barley by copper and nickel application. Symptoms of iron deficiency appeared only in the oat plants, their incidence being correlated with the reduction in iron concentration in the tops.
The ferric salt of EDTA tended to reduce the incidence of iron deficiency symptoms produced in oat by copper sulphate, but also gave rise to distinct toxic effects. Plants given the cupric salt of EDTA contained unusually large amounts of iron.     

Some Microscopical Observations of Functioning Sieve Tubes of Heracleum using Nomarski Optics

The study of isolated phloem in Heracleum has been extendedto intact functioning sieve tubes. Techniques of phloem dissectioncombined with Nomarski interference optics have been developedto permit useful visual observations, photomicrography, andciné photographs of sieve tubes which are apparentlynormal. In these preparations, plastids and organelles calledby us ‘marker particles’ are visible in rapid bouncingmotion, and the state of dispersal of these particles is relatedto the amount of damage done to the preparations. The movement of the marker particles and their subsequent fixationshows that they are apparently attached to or restrained byan invisible network in situ. The network is very sensitiveto disturbance and readily collapses around the sieve platesto form slime plugs upon damage to the sieve element. The markerparticles do not move through the cell nor across sieve platesin mature Heracleum. In young cells cyclosis is observable alongthe periphery and this suggests that a vacuole may then be present.In undamaged mature cells there was evidence neither of a vacuolenor of trans-cellular tubules of any size optically detectable. The motion of the particles was greater than Brownian movementand appeared to be under some physiological control. Their movementprobably indicated the presence of an operating transport phenomenon,either because solution was moving past them in the sieve tubeor because they were themselves attached to a contractile networkactively in pulsatory motion. Nearby companion and parenchymacells showed normal cytoplasmic streaming. Proposed mechanisms of translocation involving cytoplasmic streamingdo not seem to be applicable to the phloem of Heracleum. Themovement of the marker particles seemed to agree best with amechanism of ‘activated’ mass flow.     

Salt Retention by Bean Hypocotyl

The ultrastructure of hypocotyl, epicotyl, and petiole of bean(Phaseolus vulgaris, L.) was investigated in plants grown ina basic solution in the absence or presence of high levels ofchloride salts. The hypocotyl tissue of both control and salt-treatedplants showed frequent vesiculation similar to that previouslyobserved in the root and hypocotyl of the halophyte, Salicorniaeuropea, L. These vesicles were not previously observed in theroot and leaf of bean plants that were grown under identicalconditions in the absence of high levels of chloride salt. Experiments concerning the localization of chloride as electron-densesilver-complex showed that the vesicles contain a chloride concentrationas high as the cytoplasmic phase or the free space. These resultsare discussed in relation to the ionic retention property ofthe bean hypecotyl and the role of vesiculation in salt resistanceof plants.     

Influence of chromium(lll) on root-associated Fe(lll) reductase in Plantago lanceolata L.

The application of low chromium concentrations (5 M CrCI₃)decreased chlorophyll content of iron-deficient plants, butdid not cause visual toxicity symptoms in iron-sufficient plants.No significant plant growth differentials were obtained in responseto the various treatments. Chromium application to iron-deficientPlantago lanceolata L. roots increased the activity of root-associatedFe(lll) reductase. This effect was evident only with acceptorsof the turbo reductase and was not observed in iron-sufficientplants. Chromium accumulated in the roots, but was poorly transportedto the leaves. In split-root experiments, which allowed onlya part of the root system to receive chromium, while the otherportion was grown in iron-free medium, roots subjected to eithertreatment showed an intermediate FeEDTA reductase activity withrespect to non-split control plants. It is concluded that amobile factor from the leaves modulates the degree of expressionof the iron stress response. Possible mechanisms by which chromiumaffects Fe metabolism are discussed. Key words: Plantago lanceolata, ferric iron reduction, chromium, iron nutrition, shoot-to-root communication     

Growth and flowering of Lemna paucicostata I. General aspects and role of chelating agents in flowering

Lemna paucicostata HEGELM. is normally a short-day plant andflowers only in the presence of a chelating agent (EDTA or EDDHA)in the medium. The plant can be induced to flower even by asingle long night treatment; the flowering percentage, however,increases with further inductive cycles. The length of the criticaldark period depends upon the chelating agent employed in themedium. It is between 10 and 12 hr in the medium containingEDTA and about 8 hr in the EDDHA-supplemented medium. Red lightinterruption in the middle of the dark period—even fora minute—is inhibitory for flowering. Attempts to identify the metal ion(s) chelated reveal that thechelating agents affect flowering by facilitating iron uptake.This is also supported by the fact that the requirement of achelating agent for flowering can be overcome with an excessof iron in the medium. Interestingly, provision of EDDHA andexcess of ferric citrate, together, can bring about floweringeven under long days. ¹Originally HEGELMAIER (1) designated L. paucicostata as a separatespecies; however, THOMPSON (2) and DAUBS (3) have treated itsynonymous to L. perpusilla. More recently, based on physiologicaland chemotaxonomic studies, the distinctiveness of L. paucicostatafrom L. perpusilla has been favoured (4, 5). (Received September 8, 1969; )     

Floral Induction in a Photoperiodically Neutral Duckweed, Lemna paucicostata Strain LP6: Role of Chelating Agents and Iron

Lemna paucicostata, strain LP₆, does not ordinarily flower underany photoperiodic schedule, when grown in the modified Bonner-Devirianmedium supplemented with 10^–4 M EDTA and 1% sucrose (thisis a medium which is otherwise satisfactory for short day inductionof flowering of other strains of this duckweed). However, when the ferric citrate concentration in the culturemedium containing EDTA was raised 10-fold over that in the normalmedium, a low but significant flowering could be initiated inthis duckweed, irrespective of the length of the photoperiod.A similar flowering response was obtained when ferric citratewas replaced by ferrous sulphate or ferric chloride, therebyindicating that the inductive effect of higher level of ferriccitrate on flowering in strain LP₆ is due to its iron component. Some flowering in this strain could be induced even in mediumcontaining normal level of iron, provided the level of EDTA,itself, was raised to 5?10^–4 (5% flowering) or to 10^–3M (12% flowering), but replacement of EDTA by EDDHA led to trulyremarkable effects. With EDDHA, flowering could be induced at very high levels (90%)under all photoperiodic regimes tried. Floral initiation couldbe obtained even with 10^–6 M EDDHA, though the optimallevel ranged from 5?10^–6 to 10^–5 M. (Received October 4, 1985; Accepted June 26, 1986)     

Seasonal Production of Secondary Phloem in the Twigs of Certain Tropical Timber Trees

Secondary phloem production in four deciduous (Albizzia lebbeck,Dalbergia sissoo, Tectona grandis and Terminalia crenulata)and three evergreen plants (Calophyllum inophyllum, Mangiferaindica and Morinda tinctoria) is briefly described. The totalduration of phloem production for each year was worked out forall these plants. In three of the four deciduous trees therewere two instalments of phloem production in correspondencewith the presence of two flushes of cambial activity while inTectona grandis and in all the three evergreen trees there wasonly one instalment. The time of initiation and cessation ofphloem tissue production was found to be variable in the differentplants studied. Periodicity in the production of different componentsof phloem tissue as well as the difference in the dimensionsof the different phloic elements produced during each flushof cambial activity resulted in detectable growth increments(or ‘rings’) within the phloem. There was a distinctshortening of the different phloem elements during the approachof dormancy/least activity. Conspicuous changes were found inthe ergastic contents of phloem parenchyma and ray cells adjacentto the cambial zone during the initiation of cambial activityand during the approach of dormancy/least activity. Seasonal growth, secondary phloem, deciduous and evergreen trees, cambial activity