Root cortical aerenchyma inhibits radial nutrient transport in maize (Zea mays)

Background and Aims

Formation of root cortical aerenchyma (RCA) can be induced by nutrient deficiency. In species adapted to aerobic soil conditions, this response is adaptive by reducing root maintenance requirements, thereby permitting greater soil exploration. One trade-off of RCA formation may be reduced radial transport of nutrients due to reduction in living cortical tissue. To test this hypothesis, radial nutrient transport in intact roots of maize (Zea mays) was investigated in two radiolabelling experiments employing genotypes with contrasting RCA.

Methods

In the first experiment, time-course dynamics of phosphate loading into the xylem were measured from excised nodal roots that varied in RCA formation. In the second experiment, uptake of phosphate, calcium and sulphate was measured in seminal roots of intact young plants in which variation in RCA was induced by treatments altering ethylene action or genetic differences.

Key Results

In each of three paired genotype comparisons, the rate of phosphate exudation of high-RCA genotypes was significantly less than that of low-RCA genotypes. In the second experiment, radial nutrient transport of phosphate and calcium was negatively correlated with the extent of RCA for some genotypes.

Conclusions

The results support the hypothesis that RCA can reduce radial transport of some nutrients in some genotypes, which could be an important trade-off of this trait.     

Effect of sub-optimal root zone temperatures at varied nutrient supply and shoot meristem temperature on growth and nutrient concentrations in maize seedlings (Zea mays L.)

Maize seedlings were grown for 10 to 20 days in either nutrient solution or in soils with or without fertilizer supply. Air temperature was kept uniform for all treatments, while root zone temperature (RZT) was varied between 12 and 24°C. In some treatments the basal part of the shoot (with apical shoot meristem and zone of leaf elongation) was lifted up to separate the indirect effects of root zone temperature on shoot growth from the direct effects of temperature on the shoot meristem.Shoot and root growth were decreased by low RZT to a similar extent irrespective of the growth medium (i.e. nutrient solution, fertilized or unfertilized soil). In all culture media Ca concentration was similar or even higher in plants grown at 12 as compared to 24°. At lower RZT concentrations of N, P and K in the shoot dry matter decreased in unfertilized soil, whereas in nutrient solution and fertilized soil only the K concentration decreased.When direct temperature effects on the shoot meristem were reduced by lifting the basal part of the shoot above the temperature-controlled root zone, shoot growth at low RZT was significantly increased in nutrient solution and fertilized soil, but not in unfertilized soil. In fertilized soil and nutrient solution at low RZT the uptake of K increased to a similar extent as plant growth, and thus shoot K concentration was not reduced by increasing shoot growth rates. In contrast, uptake of N and P was not increased, resulting in significantly decreased shoot concentrations.It is concluded that shoot growth at suboptimal RZT was limited both by a direct temperature effect on shoot activity and by a reduced nutrient supply through the roots. Nutrient concentrations in the shoot tissue at low RZT were not only influenced by availability in the substrate and dilution by growth, but also by the internal demand for growth.     

RNA Synthesis in the Root Apex of Zea mays

The rate of RNA synthesis in eight regions of the root apexof Zea mays has been determined. Cells of the quiescent centrehave a lower level of RNA synthesis than any other region studied.The level of RNA synthesis appears to be a function of the positionof the cell in the apex. All the newly synthesized RNA detectedin chromatin and cytoplasm can be accounted for by synthesisin the nucleolus and subsequent transport to these compartments.Newly synthesized RNA appears in the three compartments at differentrates depending on the location of the cell.     

Longitudinal Water Movement in the Primary Root of Zea mays

The rates of transfer of tritiated water (THO) along lengthsof excised primary roots of Zea mays have been measured undera variety of conditions. The following values of ‘apparentdiffusion coefficients’ for THO in the root tissue havebeen evaluated: 1.5±0.1x10^-5 cm² sec^-1 in roots boiledfor 3 min before use,0.5±0.03x10^-5 cm² sec^-1 in rootspoisoned with 10^-2 M NaF,0.9±0.07x10^-5 cm² sec^-1 in rootspoisoned with 10^-2 M NaN₃,and 2.1±0.2x10^-5 cm² sec^-1in normal roots. The bathing medium in all cases was 1.0 mMKCl/0.1 mM CaCl₂ with the addition of the inhibitors where appropriate.Thefourfold increase in the rate of THO transfer in normal rootscompared with poisoned ones is attributed to the existence ofa long-distance convective flow in the first case, which isterminated by the addition of inhibitors. Since experimentsshow that this convective flow must occur both acropetally andbasipetally with equal velocity, it is thought to occur in thephloem.By assuming the ‘streaming transcellular strands’model for phloem transport, the rate of movement required togive the observed transfer has been computed as approximately4.5x10^-2 cm sec^-1 (160 cm h^-1).The earlier report of the existenceof a highly impermeable barrier surrounding the xylem vesselshas been further substantiated by the experiments reported here.     

Uronide Deposition Rates in the Primary Root of Zea mays

The spatial distribution of the rate of deposition of uronic acids in the elongation zone of Zea mays L. Crow WF9 × Mo 17 was determined using the continuity equation with experimentally determined values for uronide density and growth velocity. In spatial terms, the uronide deposition rate has a maximum of 0.4 micrograms per millimeter per hour at s = 3.5 mm (i.e., at the location 3.5 mm from the root tip) and decreases to 0.1 mg mm⁻¹ h⁻¹ by s = 10 mm. In terms of a material tissue element, a tissue segment located initially from s = 2.0 to s = 2.1 mm has 0.14 μg of uronic acids and increases in both length and uronic acid content until it is 0.9 mm long and has 0.7 μg of uronide when its center is at s = 10 mm. Simulations of radioactive labeling experiments show that 15 min is the appropriate time scale for pulse determinations of deposition rate profiles in a rapidly growing corn root.     

Free Radicals in the Root System and Stem of Zea mays

The concentration of free radicals in different parts of theroot system and the stem of 130, 158 and 165 d old maize plantswere measured. The highest concentrations of free radicals werefound in the tissue of the primary root and in the adventitiousroots of the 1st and 2nd nodes. In the stem tissues, the highestconcentration of free radicals was found in the tissues of the14th to 15th internode. The concentration of free radicals inthe tissues of the nodal roots decreased with increasing nodenumber, whereas in the tissues of the overground stem it increasedwith internode number. This pattern may be correlated with themetabolic activity of tissues.     

The Exchange of sodium Ions in the Root of Zea mays

The apparent cation-exchange capacity of maize roots has beenestimated in 100 mM NaCL and I mM NaCl by observing the effluxkinetics of isotopically labelled sodium from this tissue. Thisapproach indicated that the apparent capacity was 70 m.equiv/kgof tissue (fresh weight) and 2 m.equiv/kg of tissue (fresh weight)in 100 mM and I mM NaCl respectively; the pH of the medium was5.8 in each case.Similar sodium efflux experiments were performedon isolated stelar tissue from these roots and such experimentsgave an apparent exchange capacity of 86 m.equiv/kg of tissue(fresh weight) and 6 m.equiv/kg of tissue (fresh weight) in100 mM and I mM NaCl respectively, both at pH 5.8.The dependenceof the magnitude of the apparent exchange capacity upon theelectrolyte concentration of the external medium is discussed.     

Chimeras and the Origin of Lateral Root Primordia in Zea mays

The difficulty of determining the contribution made by the pericycleand endodermis of mother roots to lateral primordia in the Gramineaehas been solved by inducing polyploid chimeras at initiation. The endodermis forms a layer covering the primordium, but thislayer does not form the epidermis of the lateral. It does formthe root cap of the young primordium, but this is replaced ata variable stage of development by the quiescent centre donatinga new set of cap initials of pericyclic origin. Reasons forthe previous diversity of interpretations are presented. chimera, lateral root primordia, Zea mays     

土施L-蛋氨酸、L-苯基丙氨酸、L-色氨酸对玉米生长和养分吸收的影响

通过盆栽试验,研究了3种植物生长调节剂前体物质对玉米生长发育和养分吸收的影响,并确定了其适宜用量.结果表明,土施L蛋氨酸(L-MET)、L-苯基丙氨酸(L-PHE)和L-色氨酸(L-TRP)能不同程度地增加玉米株高、地上部和地下部干重,提高玉米根系活力、体内硝酸还原酶和过氧化氢酶的活性,促进玉米对氮、磷、钾、锌养分的吸收.在所有供试浓度中,以土施L-MET0.0185～0.185mg·kg^-1、L-PHE0.2mg·kg^-1和L-TRP0.03～0.3mg·kg^-1效果最佳,而且L-PHE和L-TRP对玉米生长的促进作用和提高养分的吸收能力均优于L-MET.     

A Correlation between Structure and Function in the Root of Zea mays

The exudation rates of fluid and potassium ions from isolatedmaize roots were determined before and after excision of certainlengths of root tip. The results of this study suggest thatexcised maize roots possess the ability to absorb potassium(and presumably chloride) ions and concomitant amounts of waterover a considerable distance (10 cm) from the tip. Moreover,the observed power of absorption of ions and water into thetranslocatory pathway decreases in passing from the tip towardsthe base of the root. Both light and electron microscope techniques were used to examinethe anatomy of primary roots similar to those used in the physiologicalexperiments. The principal observation was that the xylem vesselsnear the root tip contain membrane-bounded cytoplasm with organelles.The number of mature xylem vessels, i.e. without cytoplasm,progressively increased in transverse sections cut from 1 to10 cm from the root tip; above 10 cm from the root tip all ofthe xylem vessels were found to be completely mature. It isevident that prima facie a connexion exists between this singleaspect of root anatomy and fluid exudation from excised roots. The uptake of tritiated water by roots and its transport intoexudates was examined. These data were analysed on the assumptionthat the exchange of external labelled water with the exudatewas achieved by the fluid exudation itself; this analysis indicatedthat an operational volume, similar to that of the total xylemvolume within the root, must become labelled during the formationof the exudate.     

阴湿环境对玉米杂交种生长发育特性的影响

比较了在人工遮光增湿环境和自然环境下18个玉米杂交种生长发育特性的差异,研究了阴湿环境对玉米杂交种生长发育特性的影响.结果表明: 遮光增湿环境使空气湿度比自然环境增加15.0%～16.4%,土壤湿度增加27.0%～78.4%,光照强度降低72.9%～77.9%,光量子减少72.8%～79.6%,差异均达显著或极显著水平,但不影响环境温度.阴湿环境导致玉米植株第7叶宽、有效功能叶数、成株叶片数、雄穗分枝数、茎粗、株高、穗位高、穗长、穗粗、穗行数、行粒数、百粒重和单株粒重13个性状表现为负向变异(表型值变小),其中单株粒重降幅达72.3%,株高降幅7.1%,其余性状降幅介于14.8%～53.8%之间;第7叶长、第7叶长宽比、散粉至抽丝间隔天数(ASI)、小斑病指数和纹枯病指数等5个性状表现为正向变异(表型值增大),分别增大39.8%、80.5%、114.3%、73.0%和54.8%.用ASI、雄穗分枝数、成株叶片数、株高、单株粒重、小斑病指数和纹枯病指数7个性状计算出的综合耐阴湿系数作为玉米杂交种耐阴湿鉴定的指标,具有一定的可靠性,且简便易行.运用该指标可将18个杂交种划分为耐阴湿性强、耐阴湿性中等和耐阴湿性弱3类.     

The effect of soil aggregate size on early shoot and root growth of maize (Zea mays L.)

Differences in plant growth arising from differences in aggregate size in the seedbed are normally atributed to limitations in nutrient or water supply during the early growth period. This study was initiated to determine if these were the only mechanisms by which aggregate size influences plant response. Four different aggregate size fractions (less than 1.6 mm, 1.6 to 3.2 mm, 3.2 to 6.4 mm and 6.4 to 12.8 mm diameter) were sieved from a silt loam soil. Nutrients were added to the soil and maize was grown in the aggregates for eighteen days after seedling emergence. Soil matric potential was maintained between — 3 and −20 kPa. Shoot dry weight declined by 18% as aggregate size increased from less than 1.6 mm to 1.6–3.2 mm. There was little further decline as aggregate size increased to 6.4–12.8 mm. Final leaf area showed a similar decline. The availability of nutrients or water were not limiting. Total root length in the coarsest aggregate system was less than 60% of that in the finest system. Main axes of seminal and nodal roots were longer in the coarser aggregate systems, the length of primary laterals was not affected, and length of secondary laterals was lower in the coarser systems. A greater proportion of the roots penetrated the larger aggregates than the smaller aggregates; however, the larger aggregates offered greater resistance to penetration by a rigid micropenetrometer (150 μ diameter probe). Diameter of the main axes roots were greatest in the largest two aggregate fractions. it is speculated that a combination of increased endogenous ethylene in roots in the finest aggregate system due to entrapment by water and increased mechanical resistance in the coarsest aggregate system accounts for the observed effects on root norphology.     

Mycorrhizal symbiosis and phosphorus fertilization effects on Zea mays growth and heavy metals uptake

Arbuscular mycorrhizal fungi (AMF) can promote plant growth and reduce plant uptake of heavy metals. Phosphorus (P) fertilization can affect this relationship. We investigated maize (Zea mays L.) uptake of heavy metals after soil AMF inoculation and P fertilization. Maize biomass, glomaline and chlorophyll contents and uptake of Fe, Mn, Zn, Cu, Cd and Pb have been determined in a soil inoculated with AMF (Glomus aggregatum, or Glomus intraradices) and treated with 30 or 60 µg P-K₂HPO₄ g^?1 soil. Consistent variations were found between the two mycorrhizal species with respect to the colonization and glomalin content. Shoot dry weight and chlorophyll content were higher with G. intraradices than with G. aggregatum inoculation. The biomass was highest with 30 µg P g^?1 soil. Shoot concentrations of Cd, Pb and Zn decreased with G. aggregatum inoculation, but that of Cd and Pb increased with G. intraradices inoculation. Addition of P fertilizers decreased Cd and Zn concentrations in the shoot. AMF with P fertilization greatly reduced maize content of heavy metals. The results provide that native AMF with a moderate application rate of P fertilizers can be exploited in polluted soils to minimize the heavy metals uptake and to increase maize growth.     

Experimental Modification of Cell Division Patterns in the Root Meristem of Zea mays

In the meristem of the young primary root of maize seedlingsthe first transverse division in the cortex 250 µm fromthe root apex results in two daughter cells of distinctly unequalsize. This division could be rendered equal by raising the seedlingsin up to 7.5% methanol. The pattern of the subsequent two orthree transverse divisions in the cortex, as revealed by thearrangement of the newly divided cells in the resultant cellularpackets, was acropetal in the methanol-treated roots but basipetalin the control roots. The sequence of division within a cellularpacket tended to follow the distribution of cell sizes - largercells divided earlier than smaller cells. A temporary arrestof cell division by exposing roots to cold (5 °C) conditionshad no effect on the sequence of divisions that followed whenthe roots were allowed to recover at 20 °C. The resultssuggest that the normally asymmetric position of the cell wallformed at cytokinesis is subject to active regulation and thatmethanol interferes with this process. The cytoplasm of certaincells in the root meristem was also found to be unequally distributed,as judged by Azure B staining, between the two ends of the cell.Cytoplasmic asymmetry was not directly correlated with inequalityof division, although it too was affected by methanol. Cell polarity, root meristem, unequal division, Zea mays     

Exit from the Mitotic Cycle in Root Meristems of Zea mays L.

The choice between two modes of exit from the mitotic cycleat the margins of meristems has been made easier by surveyingthe range of the numbers of cell contacts between contiguousfiles in root apices of Zea mays L. The range shows that somecells must go out of cycle while others remain in cycle forat least three further generations. The view that cycling endsby a fall in the proliferative fraction is supported by theexistence of pulse-labelled telophases in the proximal regionof the menstem. These are most likely due to acceleration ofthe mitotic cycle which has to be contrasted with decelerationof the overall rate of cell proliferation. The work is discussedin relation to patterns of cycling in the different tissuesof the apex. mitotic cycle, cell size, meristem, proliferative fraction, Zea mays L, maize     

Effects of applying etnylene to the root system of Zea mays on growth and nutrient concentration in relation to flooding tolerance

Previous studies have shown increases in the concentration of ethylene in the soil and roots of plants when the soil is water saturated (flooded). In Zea mays L. this occurs in association with an overall reduction in growth but without extensive foliar senescence and in conjunction with the development of an adventitious root system. We have assessed the possibility that ethylene may be involved in these responses to flooding. Mixtures of the gas in air were therefore supplied to the roots and stem-base of Z. mays growing in nutrient solution.
Seven or 14 d exposure to ethylene (1 or 5 νl 1⁻¹) inhibited seminal root elongation and growth in dry weight and accelerated the emergence of adventitious roots, although their final length and dry weight were depressed. Leaf extension was inhibited by 0.1,1.0 or 5.0 μl 1⁻¹ ethylene around the roots; leaves extending rapidiy at the start of treatment were the most sensitive. Final shoot fresh and dry weights were depressed by the gas but tie shootrroot dry weighl ratio and percentage dry matter were not affected greatly. Leaf chlorosis was not observed but the concentration of phosphorus in the shoots was 26 to 31% below normal.
When aeration of the nutrient solution was stopped, the concentration of dissolved oxygen declined and the concentration of ethylene in the roots increased. Similar changes occur in response to soil flooding. Root and shoot growth was slowed by non-aeration although the shootroot dry weight ratio remained unchanged. The phosphorus concentration of the shoots was depressed but there was little chlorosis or leaf death. The similarity in these respects between the effects of ethylene and non-aeration suggests that in flooded Z. mays , ethylene contributes to their development by accelerating the emergence of adventitioos roots, inhibiting phosphorus accumulation in the shoots and by a non-toxic inhibition of plant growth.     

The Effect of High Concentrations of Heavy Water on Root Morphogenesis in Zea mays

The effect of high concentrations of heavy water on young rootsof Zea mays was investigated. Submersion for 24 hrs. in solutionsof 80–90 per cent. D₂O will temporarily stop growth ofthe primary root. During the treatment period the root-tip regionswill swell as the result of radial cell enlargement, primarilyin the cortical region. Upon removal from D₂O growth will resume,initially at a slower rate than controls but ultimately at similarmaximum rates. Lateral root production is inhibited in thatportion of the primary root which is the region of elongationat time of treatment. However, in the swollen region lateralroot formation is accentuated. The mitotic index drops sharplyupon introduction of the primary roots into 80 per cent. D₂O.Within 12 hrs. the index drops to zero and remains at this leveluntil the roots are removed from the heavy water. The mitoticindex then rises again, reaching control values within 24 hrs.It is suggested that the gentle, temporary inhibitory actionof D₂O makes this substance a useful tool in morphogenetic investigations.     

Extracellular Calmodulin Stimulates the Transplasma Membrane Redox Reaction of Root Protoplasts in Zea mays

Using ferricyanide as the membrane impermeable electron acceptor, the effects of extracellular calmodulin on transplasma membrane redox reaction of the root protoplasts in Zea mays L. were studied. The calmodulin antagonists (calmidazolium, W7-agarose) and anti-calmodulin serum had inhibitory effect on the extracellular reduction of ferricyanide with their concentration that yielded 50% inhibition were 1.5 μmoL/L, 10 μmol/L and 10 mg/L respectively. Inhibition of calmidazolimn could be restored by calmodulin completely. And the reduction of ferricyanide could be specifically stimulated by the exogerous purified calmodulin. These results suggested that transplasma membrane redox system of root protoplasts in Zea mays L. could be modulated by calmodulin outside the plasma membrane.     

Effect of different levels of humic acids on nutrient content and growth of corn (Zea mays L.)

Summary The effect of humic acids on nutrient uptake and growth of corn plants (Zea mays L.) was investigated by growing corn in plastic growth pouches containing a Hoagland nutrient solution to which were added 0, 320, 640, 1,600 or 3,200 ppm HA, pH 7.0. The experiments were carried out in three replicates for a growing period of 16 days after germination. Humic acid was in general beneficial to shoot and root growth of corn plants. Dry matter yield in corn shoots was stimulated by HA, especially by treatments with 640 ppm HA. Nutrient uptake showed a number of differences as a result of treatments with HA. Moderate applications with HA resulted in a significant increase in N content of corn shoots, while large amounts of HA had a tendency to reduce the N concentration in corn shoots. As a result of the HA treatments, P concentrations in corn shoots were decreased, but differences in K contents were statistically nonsignificant and Mn contents in shoots were also nonsignificantly different among the treatments. However, Zn content showed a tendency to increase with increasing applications of HA.Contribution of the University of Georgia, College Agri. Exp. Stn., College Stn., Athens, GA 30602. Current address of junior author: c/o Soil and Fertilizer Section, Field Crop Division, Department of Agriculture, Bangkok, Thailand.