Root-shoot signalling in sunflower plants with confined root systems

Sunflower plants were grown hydroponically under controlled conditions with the root systems confined in small containers. Root confinement inhibited the growth of sunflower plants as indicated by reduction in both leaf and cotyledon area and root and shoot fresh weight. This effect was more pronounced in shoots. Root confinement favored the accumulation of potassium in the roots and shoots, and the exudation of potassium and water in excised roots. Xylem sap from root confined plants inhibited cotyledon expansion as revealed by bioassay with decapited sunflower seedlings. In addition decapited control plants incubated in ABA solution also showed cotyledon growth reduction. Xylem sap ABA analysis indicated a 7-times higher concentration in root confined than control plants. Our results suggest the synthesis of a chemical signal in the roots of plants subjected to mechanical stress which can be responsible for the inhibition of plant growth.     

Effects of Pyrenochaeta lycopersici infection on nutrient uptake by tomato plants

The growth of young tomato plants in nutrient solution or in soil and infected with Pyrenochaeta lycopersici Schneider & Gerlach, the cause of tomato brown root rot, was decreased relative to that of uninfected plants. The roots of plants grown in nutrient solution and infected with a mycelial mat of the pathogen contained lower concentrations of potassium and higher concentrations of calcium than roots of uninfected plants. These changes occurred largely in the visibly affected tissue, as opposed to the root system as a whole. The concentrations of magnesium, total nitrogen and phosphorus in the roots of infected plants were not significantly different from those of control plants. Magnesium, nitrogen and phosphorus concentrations in the tops of infected plants were also not significantly different from those of healthy plants, but no consistent changes were found in the concentrations of calcium and potassium. Young tomato plants grown in soil infested with P. lycopersici contained lower concentrations of phosphorus and potassium in the tops than plants grown in sterilized soil. It was not possible to separate intact damaged root systems of infected plants from soil. The changes in composition found in infected plants are discussed in relation to possible methods of manipulating the nutrition of the plant to offset the effects of the disease on crop yield.     

Ion Uptake Efficiency of Sunflower Roots

The term ion uptake efficiency is used for the rate of uptake of a particular ion from nutrient solutions holding a standard concentration of that ion (0.5 mM sulphate, 1.5 mM phosphate or 2.0 mM rubidium). The uptake efficiency for rubidium and phosphate in roots of intact sunflower plants depended on the salt status of the plants and on the concentration of the ion under investigation in pretreatment solutions. The effect of pretreatment was a rapid process causing differences of more than 300% in ion uptake efficiency within 1 h, depending on the composition of the pretreatment solution. At concentrations above 0.1 mM the rate of uptake of rubidium in the root was higher than the net potassium uptake necessary for adequate growth. The rate of sulphate uptake was related to potassium uptake but not to phosphate uptake. It is suggested that ion uptake of the roots is regulated by internal factors as well as by direct interactions between the medium and the absorbing surfaces.     

A Study of the Relationship between Root and Shoot Metabolism

The influence of light and dark on the respiration rate, sugarlevel, and rubidium uptake of the roots of young sunflower andbarley plants has been investigated. The rate of root respirationwas found to be closely correlated with the rate of carbohydratetransport from the shoots. This enabled the energy requiredfor root growth to be calculated. A period of darkness causeda reduction in rubidium uptake and transport which appearedto be due to the reduced rate of root metabolism in the dark.The experiments of some earlier workers on the effect of transpirationon rubidium uptake by young sunflower and barley plants wererepeated. The results indicated that they were studying themetabolic effect of light and dark on salt uptake as well asthe effect of transpiration.     

河西干旱区白芍养分吸收规律与药效成分积累的关系研究

为揭示河西干旱区白芍干物质积累及营养元素吸收特征和药效成分累积规律,明确影响药效成分积累的营养元素种类,科学制定白芍施肥方案和规范化种植。以甘肃省古浪县古丰镇芍药产业基地4年生白芍为研究对象,通过田间试验测定白芍不同生长期干物质积累特征以及根中9个营养元素含量和3类药效成分含量,并分析白芍根中有效成分含量与营养元素的相关关性。结果表明：（1）随着生育期延续,白芍根部干物质积累先下降后上升,全株干物质积累量逐渐增加,出苗后90-130 d是白芍干物质积累最快的时期,占总积累量的79.29 %,是白芍生长的关键时期。（2）白芍地上部氮、钾含量总体呈下降趋势,而磷素含量总体呈明显增加趋势,而根部氮、磷含量总体呈减少趋势,钾含量变化不明显;地上部和根氮累积总量分别在出苗后130 d和150d达到最高。地上部磷积累量在出苗后150 d达到最大,根部磷积累量分别在出苗后30 d、150 d达到高峰,地上部和根部钾积累量分别在出苗后70 d和150 d达到高峰。地上部氮、钾含量在不同生长时期均高于根部,其磷含量则在出苗后90 d前低于根部,在出苗后110 d后高于根部。（3）根中芍药苷、芍药内酯苷积累量均先升高后降低,最后趋于稳定,多糖积累量表现为高-低-高的变化趋势。（4）芍药苷含量与氮、钙、铜含量呈极显著正相关,与钾含量呈显著正相关,芍药内脂苷含量与氮、钾、钙、铜含量呈极显著正相关,而芍药多糖与各营养元素含量之间没有相关性。可见,白芍氮、磷、钾营养最大效率期在出苗后110～150 d,适时追加氮、钾肥有利于根部生物量的积累,施肥中添加Ca、Cu元素能有效促进白芍药效成分的积累;河西冷凉山区白芍宜在9月中下旬（9月16日以后）采挖。     

Growth of the Tops of Sweet Potato and the Translocation of the Nutrients from Leaves

1. Experiments were carried out in Hangchow on the increase of dry matter in the tops of sweet potato plants. The increase can be divided into three periods: (1) slow accumulation of dry matter; (2) rapid increase of accumulation of dry matter, reaching a maximum; (3) decline of accumulation of dry matter, later on account of senility and the dropping of leaves, there was a marked reduction in the dry matter of the tops. The increase in dry matter is in proportion to the leaf area. The amount of fertilizer used is closely related to the increase of dry matter and leaf area. 2. The yield of sweet potato is related to the increase in dry matter of the tops of the plant. To a certain extent, the greater the amount of dry matter, the more rapidly will the tubers enlarge, finally results in a higher yield. Excessive use of fertilizer leads to an abnormal elongation of the plant. During this period an increase in dry matter of the tops not only fails to induce the enlargement of the tubers, but also leads to the consumption of the dry matter, and consequently causes a reduction in yield of sweet potato. From the curve of T/R ratio, the sooner the downward translocation of the tops nutrients occurs, the faster the tubers will form and enlarge. 3. Experiments with p32 show that the various growth conditions of the tops are closely correlated with the translocation of the tubers. With well growing and high yielding plants the nutrients move from the tops to the tubers as soon as the root enlarges. This translocation is even accelerated during the later stage. During the earlier stage of development, much of the plant nutrition is translocated to the stems and leaves, particularly to the latter; then gradually it is diverted to the leaves and the root system, and finally concentrates in the roots. The increase of the area of green leaves and the number of branches during the period of early growth, and the promoting of favourable conditions for the formation and enlargement of the roots, as well as the facilitating of the translocation of nutrients to the roots during the later stage are the determinative factors necessary for obtaining high yield of sweet potato.     

Root-zone temperature and salinity: Interacting effects on tillering,growth and element concentration in barley

The effects of root-zone salinity (0, 30, and 60 mmol L^–1 of NaCl) and root-zone temperature (10, 15, 20, and 25°C) and their interactions on the number of tillers, total dry matter production, and the concentration of nutrients in the roots and tops of barley (Hordeum vulgare L.) were studied. Experiments were conducted in growth chambers (day/night photoperiod of 16/8 h and constant air temperature of 20°C) and under water-culture conditions. Salinity and root temperature affected all the parameters tested. Interactions between salinity and temperature were significant (p<0.05) for the number of tillers, growth of tops and roots, and the concentration of Na, K, P in the tops and the concentration of P in the roots. Maximum number of tillers and the highest dry matter were produced when the root temperature was at the intermediate levels of 15 to 20°C. Effect of salinity on most parameters tested strongly depended on the prevailing root temperature. For example, at root temperature of 10°C addition of 30 mmol L^–1 NaCl to the nutrient solution stimulated the growth of barley roots; at root temperature of 25°C, however, the same NaCl concentration inhibited the root growth. At 60 mmol L^–1, root and shoot growth were maximum when root temperature was kept at the intermediate level of 15°C; most inhibition of salinity occurred at both low (10°C) and high (25°C) root temperatures. As the root temperature was raised from 10 to 25°C, the concentration of Na generally decreased in the tops and increased in the roots. At a given Na concentration in the tops or in the roots, respective growth of tops or roots was much less inhibited if the roots were grown at 15–20°C. It is concluded that the tolerance of barley plant to NaCl salinity of the rooting media appears to be altered by the root temperature and is highest if the root temperature is kept at 15 to 20°C.     

Photoperiod and root-zone temperature: Interacting effects on growth and mineral nutrients of maize

Factorial effects of photoperiod (6, 12 and 18 h) and root-zone temperatures (9, 15 and 21°C) on the growth and mineral nutrient concentration and partitioning in maize (Zea mays L.) were investigated. Strong interactions were observed between photoperiod and root-zone temperature on the growth and concentration of numerous mineral elements in the plant tops and roots. For example, a threefold increase in photoperiod (from 6 to 18 h) did not affect the growth of tops or roots if the root-zone temperature was 9°C but increased them each by eightfold if the root-zone temperature was 21°C. On the other hand, raising the root-zone temperature from 9 to 21°C increased the growth of tops and root each by ca. threefold when plants were grown with 6 h of light. At 18 h photoperiod, however, plant growth was increased 20- to 30-fold by the same rise in the root-zone temperature. The concentrations of different mineral elements in the roots and tops were affected quite differently by the interacting effects of photoperiod and root-zone temperature. In general, increasing the photoperiod at a given root-zone temperature decreased the concentrations of elements while increasing the root-zone temperature at a given photoperiod increased the concentrations of most elements in both roots and tops. The exceptions were K and B which reacted opposite to each other: K concentration in both tops and roots was relatively insensitive to photoperiod but very sensitive to root-zone temperature and the reverse was true for boron. The relative insensitivity of plant growth to increased day length as long as the roots are subjected to suboptimal (low) soil temperatures may have survival significance and point to the predominant role of root temperature over that of day length in the early growth of maize. A possible mechanism by which photoperiod and root-zone temperature might interactively alter the nutrient uptake by the roots is discussed.     

Growth and Maintenance Respiration in Whole Plants, Tops, and Roots of Lolium multiflorum

Continuous measurements of CO₂-exchange were separately carried out on tops and roots of small swards of Lolium multiflorum grown in nutrient solution in growth chamber during 3–4 weeks. From these measurements, a daily carbon balance and accumulated dry matter could be established. The data were used to distinguish between two components of respiration, one proportional to growth or photosynthesis (growth respiration), the other proportional to plant dry weight (maintenance respiration). The separation of respiration in the two components was made by multiple regression analyses with daily photosynthesis or growth rate and accumulated dry matter as the independent variables. To ensure independency between the independent variables during the growth period, photosynthesis was varied by application of alternate three-day periods of high and low irradiance. From the two regression coefficients, the efficiency of converting assimilates into constructive growth (Y_G) and the maintenance coefficient (M) could be derived. Three experiments with varying length of photoperiod and dark period were carried out. The analyses were carried out for whole-plant respiration, respiration of tops and respiration of roots separately. Growth respiration for whole plants as well as for tops and for roots was lower — and hence the efficiencies higher — the longer the photoperiods were. Growth respiration and maintenance respiration were higher for roots than for tops. The high rate of root respiration may originate from release of HCO₃^? in exchange for NO₃^?. The parameters found can be utilized quantitatively in computer models of crop photosynthesis and respiration.     

Aluminium effects on growth and Al,Ca, Mg,K and P levels in triticale,wheat and rye

Summary The effects of A1 on the growth and mineral composition of different cultivars of triticale (X Triticosecale, Wittmack), wheat (Triticum aestivum L.) and rye (Secale cereale L.) growing in 1/5 strength Steinberg solutions containing 0 or 6 ppm A1 were evaluated after 32 days. Aluminum increased the concentrations of P and K in the roots and K in the tops of most of the cultivars tested. A1 tolerant triticale retained a lower concentration of Mg in the roots and tops than the A1 sensitive triticale, when subjected to A1 stress. In addition, A1 treatments resulted in smaller increases in root P for the A1 tolerant triticale than for the A1 sensitive cultivars.The concentration of root Ca and P of the A1 tolerant wheat cultivars were significantly below that of the more sensitive plants. Aluminum tolerance in rye appeared to be associated with lower Ca and higher Mg concentrations in the tops. The accumulation of P and A1 in the roots was characteristic of sensitivity in triticale, wheat and rye.     

METABOLIC PRIORITIES WITH RESPECT TO GROWTH AND MINERAL UPTAKE IN ROOTS OF HORDEUM,TRITICUM AND LYCOPERSICON

Reduction in the supply of photosynthate to the roots of tomato, barley, and wheat plants was achieved indirectly by lowering the intensity of sunlight striking the foliage of test plants. The decrease in sugar and starch concentrations in the roots was verified by appropriate extraction and colorimetric analysis, and a corresponding reduction in the total respiratory rate of the roots was confirmed using an oxygen tension monitor. Other processes measured directly include the rate of uptake of potassium, the mitotic quotient in the root tip—a measure of growth—and the rate of accumulation of dry matter in the root. The study demonstrated that of the metabolic activities observed, root growth is the process first limited when the supply of photosynthetic fuel is decreased. Root growth was severely inhibited under conditions that did not significantly affect either the active uptake of potassium per gram of root or total respiration per gram of root. With greater restriction of photosynthesis, growth was completely halted while the uptake of potassium was strongly decreased and total respiration was still affected only moderately. As the light intensity is reduced significantly, most of the reduced energy supply in the root appears to be used in support of processes critical to maintenance of the organ and the organism.     

The nutrition of the carrot

In sand-culture experiments with carrots, it was shown that a moderate quantity only of nitrogen was necessary for optimum growth compared with, for example, the turnip root. A moderate amount of (available) phosphorus was also sufficient for this purpose, as with the turnip, but contrary to experience with lettuce roots and tops. The greatest concentration of potassium applied, however, was probably the best for root development. Deficiency of phosphorus caused bronzing of the leaves, and absence of potassium, serious scorch; absence of boron resulted in a small, immature plant. Initial field trials on an old river gravel during experiments throughout the last 7 years indicated that dung gave no advantage over artificials, that artificials were possibly not needed on dunged land or land in good heart, and that land out of good heart, undunged and unfertilized throughout the 7 years, responded well to artificials, particularly phosphate and potash. The incidence of carrot fly, according to preliminary experiments, seemed to depend greatly on the nutrition of the carrots.     

Influence of Tops and Roots on Net Assimilation Rate of Sugar-beet and Spinach Beet and Grafts between them

Sugar-beet has a larger storage root and greater net assimilationrate (E) than spinach beet. To determine whether the greaterroot was a result or cause of the greater E, grafts were madebetween tops and roots of sugar-beet and spinach-beet in allfour possible combinations. Grafted plants with sugar-beet roots had greater E and rootdry weight, less leaf area and top dry weight and lower concentrationof sugar in the leaf lamina, than those with spinach-beet roots,irrespective of the type of top. Grafted plants with sugar-beettops had greater E, total and root dry weight, but less leafarea, than those with spinach-beet tops, irrespective of thetype of root. The difference in E between grafted plants withsugar-beet tops and spinach-beet tops was similar to that betweengrafted plants with sugar-beet roots and spinach-beet roots.It increased with time to 60 per cent. Increases in E probably represent increases in rate of photosynthesis.Sugar-beet roots probably increased photosynthesis by providinga better sink for assimilates than spinach-beet roots.     

黄芩干物质累积和氮磷钾吸收、分配规律研究

为了探讨黄芩干物质累积和氮、磷、钾吸收与分配的特点及两者间的相互关系,通过田间试验和采样分析,研究了黄芩不同生育期植株的干物质和氮、磷、钾累积量.结果表明,黄芩干物质的累积量随生育进程不断地增加,出苗后52～85 d干物质累积量占总累积量的61.62％.在整个生育期,黄芩对K2O的吸收累积量最大,N次之,P2O5最小,N、P2O5、K2O吸收比例约为2.8∶1.0∶2.9,并且黄芩地上部氮磷钾的累积量大于根部,不同生育期,根部N、P2O5、K2O的累积比例呈现增加—降低—增加的趋势.黄芩对氮磷钾的积累量与干物质积累量呈极显著正相关关系.在供试的土壤和施肥条件下,每生产100 kg的黄芩根需要从土壤和肥料中吸收6.34 kg的N,2.60 kg的P2O5,7.02 kg的K2O.     

Changes in Mineral Content of Eucalyptus marginata and E. calophylla Grown under Controlled Conditions and Inoculated with Phytophthora cinnamomi

Mineral concentrations in infected roots and shoots were compared with similar material, but pathogen free, for the susceptible Eucalyptus marginata and the field resistant E. calophylla. All plants were mycorrhiza-free, grown under controlled conditions and inoculated with an axenic suspension of zoospores of Phytophthora cinnamomi. Plant material was ashed 30 days after inoculation and analyzed in an external proton beam using PIXE and nuclear reaction analyis to detect differences in mineral concentrations. The mineral content of infected roots of E. marginata was below that of the uninfected roots for all elements detected except chlorine, chromium and rubidium. The reductions were significant for calcium and copper. No such reduction was found, in E. calophylla roots, but some changes were detected. Shoot: root ratios of E. marginata showed significant differences associated with infection in phosphorus, calcium, copper and zinc. Relatively large differences were also recorded for sulphur chlorine and potassium. Shoot: root ratios of infected E. calophylla showed fewer differences but contained only half the concentrations of sulphur and potassium present in the controls. The reduced mineral concentrations reflect the failure in conduction of water and minerals through the infected and susceptible root system.     

Uptake of phosphorus and potassium in relation to root growth and root density

Summary This paper provides some quantitative data on the relationship between the rate of uptake of phosphorus and potassium from soil and the amount of root, root density and rate of root growth. Three experiments were conducted with winter wheat, all grown in the same soil. Root growth and density were manipulated in three ways: (1) by root pruning; (2) by a split-root technique; (3) by growing plants in different soil volumes. Root lengths as well as weights were determined.Potassium uptake per unit amount of root was generally lower the higher the root density, suggesting that roots were competing with each other for potassium even at the lowest density. In contrast, phosphorus uptake showed a good correlation with root growth irrespective of root density or plant age. Phosphorus uptake during a period was more closely and consistently correlated with root growth during that period than with the total amount of root on the plant. The results can be explained in terms of ion supply to the root surface, taking into account the diffusion coefficients of the ions and the approximate distances between neighbouring roots.Now Mrs. Watkins; address 39 Leach Heath Lane, Rubery, Birmingham.Now Mrs. Watkins; address 39 Leach Heath Lane, Rubery, Birmingham.     

Disturbed ammonium assimilation is associated with growth inhibition of roots in rice seedlings caused by NaCl

The effects of NaCl on changes in ammonium level and enzyme activities of ammonium assimilation in roots growth of rice (Oryza sativa L.) seedlings were investigated. NaCl was effective in inhibiting root growth and stimulated the accumulation of ammonium in roots. Accumulation of ammonium in roots preceded inhibition of root growth caused by NaCl. Both effects caused by NaCl are reversible. Exogenous ammonium chloride and methionine sulfoximine (MSO), which caused ammonium accumulation in roots, inhibited root growth of rice seedlings. NaCl decreased glutamine synthetase and glutamate synthase activities in roots, but increased glutamate dehydrogenase activity. The growth inhibition of roots by NaCl or MSO could be reversed by the addition of L-glutamic acid or L-glutamine. The current results suggest that disturbance of ammonium assimilation in roots may be involved in regulating root growth reduction caused by NaCl.Abbreviations GDH glutamate dehydrogenase - GOGAT glutamate synthase - GS glutamine synthetase - MSO methionine sulfoximine     

The Distribution of Mg, P and K in the Split Roots of Subterranean Clover

The aim of these experiments was to determine whether uninhibitedroot growth is possible in a soil lacking Mg, provided thatthe plant is adequately supplied with Mg from another regionwithin the soil. Two experiments were undertaken using splitroot systems in free-draining sand or gravel irrigated dailywith nutrient solution. Magnesium supply to one half of theroot system was varied and root growth in the deficient partof the system was measured. Magnesium redistribution was comparedto that of calcium, phosphorus and potassium. Magnesium content of the roots grown in the compartment withno Mg supply increased, but only when the shoots had an adequateto luxury Mg status. Even under these conditions root growthwas inhibited compared to roots with an adequate external supplyin both compartments. Similarly potassium was transferred tothe roots with no external supply, but root growth was retardedin this compartment. Roots proliferated in the compartment suppliedwith phosphate and did so at the expense of growth in the non-supplycompartment. The shoots had a barely adequate phosphorus statusand there was no transfer of phosphorus to the root with noexternal supply. Magnesium, phosphorus, potassium, root growth, split root systems, subterranean clover, Trifolium subterraneum L.     

Accumulation of rare earth elements in maize plants (Zea mays L.) after application of mixtures of rare earth elements and lanthanum

Rare earth elements are applied in China to improve crop production, and the distribution patterns of individual rare earth elements in native plants have widely been reported. But our knowledge is still limited about the dose-dependent accumulation of individual rare earth elements in agricultural crops after application of rare earth elements. Effects of lanthanum and mixtures of rare earth elements were studied in pot experiments on the accumulation of individual rare earth elements in maize plants. All plant samples were divided into plant tops and roots. On addition of mixtures of rare earth elements and lanthanum to the soil, a significant dose-dependent accumulation of individual rare earth element(s) was found in the roots and in the plant tops. Application of mixtures of rare earth elements at >10 mg kg^–1 soil, resulted in a significant increase in contents of light rare earth elements in the roots, and at a dose of 50 mg kg^–1 soil, a similar phenomenon was found in the plant tops. When mixtures of rare earth elements were replaced by lanthanum alone, at a dose higher than 10 mg La kg^–1 soil, a significant increase in La content occurred in the roots and in the plant tops. The content ratio of La to Ce in maize plants appeared to increase as the application doses of rare earth element(s) increased. At a highest dose (50 mg kg^–1soil), the transport of the absorbed La from the roots to the plant tops might be substantially reduced after treatment with lanthanum alone, compared with mixtures of rare earth elements. Increasing the application doses of rare earth element(s) appeared to cause a positive Gd and negative Ce anomaly in the roots and in the plant tops, and the anomaly was more obvious in the plant tops than in the roots. The results indicated that the Gd and Ce anomaly in corns might be considered as important parameters for the safety assessment of agricultural application of rare earth elements.     

Growth and accumulation of N, K+, Ca2+ and Mg2+ in barley exposed to various nutrient regimes and root/shoot temperatures

Six cultivars of spring barley ( Hordeum vulgare L. cvs Salve, Nümberg II, Bomi, Risø 1508, Mona and Sv 73 608) were grown in water culture for three weeks with various combinations of mineral supply and differential roots/shoot temperatures during the growth period. Most important for growth and accumulation of N, K⁺, Ca²⁺ and Mg²⁺ was the mineral supply, followed by the root temperature and the choice of cultivar. Treatments with low mineral supply or low root temperature induced a uniform reduction in growth and accumulation of the ions studied. The effects of low mineral supply and low root temperature on growth and N accumulation was additive, which indicates that these factors exert their influence independently of each other.
Roots grown at 10°C were smaller and Rb⁺(⁸⁶Rb) influx was higher than in roots grown at 20°C. It is suggested that the control of Rb⁺(⁸⁶Rb) influx is affected by the root temperature and the age of the plants. The higher ⁸⁶Rb⁺ (⁸⁶Rb) influx into the low temperature roots could not compensate for the smaller root size. However, the lower total mineral accumulation made up for the needs of the smaller plants and cannot explain the reduction in growth.