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1.
《European Journal of Agronomy》2006,24(3):218-225
Improvements in drought tolerance of crop plants require research focused on physiological processes. In 2002 and 2003 pot experiments with sugar beet were conducted in a greenhouse. Two (2002) or three (2003) different genotypes were subjected to three watering regimes (100, 50 and 20% of water holding capacity). Gas exchange, chlorophyll fluorescence and water-use efficiency (WUE) as parameters of possible relevance for drought stress tolerance in sugar beet were investigated. It was studied whether 13C discrimination (Δ) is suitable as an indirect measure for WUE of sugar beet.DM yield, photosynthesis rate, transpiration rate and stomatal conductance decreased with increasing severity of drought stress. In contrast, internal CO2 partial pressure remained relatively stable and effective quantum yield of photosynthesis was reduced only under severe drought, which points at non-stomatal inhibition of photosynthesis. Different sugar beet genotypes showed significant differences in DM yield, but interactions between genotype and water supply did not occur, indicating that genotypic differences in drought tolerance did not exist. In accordance with that, drought-sensitivity of gas exchange and chlorophyll fluorescence was the same in different genotypes. Δ was higher in the leaves than in the taproot. Reductions in Δ in drought-stressed plants corresponded to about 24% higher WUE. Differentiating between plant organs, only leaf Δ was negatively correlated with WUEL whereas taproot Δ and WUET were unrelated. Δ was therefore proven to be a sensitive indicator for water availability during the growing period. However, similar as other parameters relevant for drought stress tolerance it requires investigations in broader genetic material of sugar beet to detect genotypic differences. 相似文献
2.
Solute Accumulation as a Cause for Quality Losses in Sugar Beet Submitted to Continuous and Temporary Drought Stress 总被引:1,自引:0,他引:1
Adaptation to low water availability in sugar beet includes the accumulation of solutes relevant for the technical quality of the beet. Two sugar beet genotypes were grown in pot experiments under drought stress of different severity to study effects on taproot composition and concentration of solutes relevant for technical quality, reversibility of drought effects after re‐watering and genotypic differences in drought response. Differences in stress sensitivity between the genotypes were not observed as reductions in taproot and leaf dry weight and white sugar yield were the same. Increasing dry matter concentration with decreasing water supply could, in part, be attributed to an increase in the concentration of cell wall components. The major solutes in the taproot were sucrose, potassium, amino N (the sum of amino acids) and betaine. Sucrose concentration decreased considerably under drought, indicating limited availability of assimilates. In contrast, all further solutes increased in concentration with increasing severity of stress. However, the response of individual solutes varied largely. Changes in amino N and nitrate were most pronounced and probably reflect accumulation of non‐utilized metabolites under limited growth. The drought‐induced accumulation of taproot solutes implicates a considerable decrease in the technical quality of the beet. It was only in part reversible by re‐watering. Genotypic variability for solute accumulation under water deficiency was observed but was not linked to drought tolerance. 相似文献
3.
C. M. Hoffmann 《Journal of Agronomy and Crop Science》2010,196(4):243-252
Drought stress may affect sucrose accumulation of sugar beet by restricting leaf development and storage root growth. The objective of this study was to identify changes occurring in the storage root of Beta beets in growth characteristics and ions and compatible solutes accumulation under drought with regard to sucrose accumulation. Two pot experiments were conducted: (1) sugar beet well supplied with water (100 % water capacity), under continuous moderate (50 %) and severe drought stress (30 %), (2) sugar beet and fodder beet well supplied with water (100 %) and under continuous severe drought stress (30 %). Under drought stress, the ratio of storage root to leaf dry matter of sugar beet decreased indicating a different partitioning of the assimilates. The sucrose concentration of the storage root was reduced. In the root, the number of cambium rings was only slightly affected, although drought stress was implemented already 6 weeks after sowing. In contrast, the distance between adjacent rings and the cell size was considerably restricted, which points to a reduced expansion of existing sink tissues. The daily rate of sucrose accumulation in the root showed a maximum between 16 and 20 weeks after sowing in well‐watered plants, but it was considerably reduced under drought stress. The concentration of compatible solutes (K, Na, amino acids, glycine betaine, glucose and fructose) decreased during growth, while it was enhanced because of drought. However, when sucrose concentration was added, a constant sum of all examined solutes was found throughout the vegetation period. It was similar in sugar beet and in fodder beet despite different concentrations of single solutes, and the total sum was not affected by water supply. A close negative relationship between the concentration of compatible solutes and sucrose occurred. It is therefore concluded that the accumulation of compatible solutes in the storage root of Beta beets under drought might be a physiological constraint limiting sucrose accumulation. 相似文献
4.
For three successive growing seasons (1999–2001), a completely randomized block design experiment was established at the surrounding area of each of four sugar beet processing plants of Hellenic Sugar Industry SA, Greece (a total of 12 experiments). Nitrogen was applied at five rates (0, 60, 120, 180 and 240 kg N ha−1) and six replications per rate. Nitrogen fertilization had site-specific effects on quantitative (fresh root and sugar yields) and qualitative (sucrose content, K, Na, α-amino N) traits. When data were combined over years and sites, fresh root and sugar yields were maximized at high N rates (330.75 and 295 kg N ha−1 respectively), as derived from quadratic functions fitted to data. In three trials, increased N rates had negative effects on root and sugar yield. These sites were characterized by high yield in control plots, light soil texture (sand > 50 %) and low CEC values. When data were converted into relative values (the ratio of the trait values to the control mean of each experiment), root and sugar yield was found to be maximized at higher N rates (350 and 316 kg N ha−1, respectively). Sucrose content was strongly and linearly reduced by the increased N rates when data were combined but a significant reduction with increasing N rates was found in only two sites. Non-sugar impurities (K, Na, α-amino N) were positively related to the increased N rates when data were combined. Sodium and α-amino N showed to be most affected by N fertilization as positive relationships were found in six and eight of 12 locations, respectively. Increased N supply resulted in higher soil NO3-N concentrations (0–90 cm depth) at harvest which were related with amino N contents in sugar beet roots (in 1999 and 2001). 相似文献
5.
《European Journal of Agronomy》2006,24(1):62-69
There is much data on the impact of weather variables on the growth of sugar beet from studies conducted under controlled conditions or single field experiments, but these data are of only limited validity for other sites or larger areas. The aim of the present study was to quantify the influence of weather conditions on the growth of sugar beet for the further development of simulation models, based on data representative of sugar beet cultivation in Germany. For this purpose, 27 field trials were conducted in 2000–2001 in commercial fields with variable climatic and soil conditions. From the end of May until the end of the season, beets were harvested manually every 4 weeks, the dry matter yield of leaves and taproot was determined and their growth rates were calculated. Temperature, solar radiation, rainfall and humidity were recorded daily for each site and the potential evapotranspiration and climatic water balance were estimated. The soil water content to a depth of 0.9 m was determined at every harvest date.Several functions were developed to describe the growth of sugar beet as affected by the given meteorological variables. From sowing to the end of June, the dry matter accumulation of both leaves and taproot was strongly enhanced by increasing temperature and during this period leaf dry matter increased linearly with thermal time. After reaching 700 °C d, the taproot dry matter accumulated exponentially with thermal time. The optimum mean daily air temperature for taproot growth was approximately 18 °C. Higher temperature occurring in July and August decreased final taproot yield, but by the end of the season, growth was independent of temperature. High solar radiation advanced growth during the first 65 days after sowing and again in October.Neither the water input by rainfall and irrigation nor the climatic water balance adequately described the growth of the leaves or taproot, but it was shown that the increase in taproot dry matter during July and August depended on the amount of available water in the soil. The maximum sugar yield that can theoretically be achieved in Germany and comparable agroclimatic regions was calculated as 24 t ha−1. The present data reliable for a large agroclimatic region in Europe are of significant value as input for simulation models. 相似文献
6.
Seyyed Gholam Reza Moosavi Seyyed Hamid Reza Ramazani Saeid Sadeghzadeh Hemayati Hamid Gholizade 《Journal of Crop Science and Biotechnology》2017,20(3):167-174
To study the effects of different levels of drought stress on root yield and some morpho-physiological traits of sugar beet genotypes, a study was conducted in the research farm of Islamic Azad University of Birjand, Iran in 2013 as strip-split plot experiments based on randomized complete block design. Different levels of drought stress were considered as vertical factor in three levels including normal irrigation, moderate stress, and severe stress. Horizontal factor was assigned to five varieties of sugar beet. Drought stress had a significant effect on root dry weight, total dry weight, root yield, and leaf temperature at 1% probability level and on leaf dry weight, crown dry weight, and harvest index at 5% probability level. Drought stress had an adverse effect on root yield of investigated genotypes of sugar beet. Under normal conditions, the mean of root yield was higher than middle and severe drought stress. Different investigated genotypes of sugar beet responded to drought stress based on their yield potential. The highest positive correlation of root yield was observed with root dry weight (r=0.977**). Stepwise regression analysis and path coefficient analysis showed that root dry weight and petiole dry weight are the most important traits that can affect root yield of sugar beet under drought stress and can used as selection criteria in investigated cultivars of sugar beet. Finally, 7221 genotypes can be considered as tolerant genotypes in the next studies. In comparison, Jolgeh cultivar (as susceptible control) yielded well in areas with normal irrigation, but under moderate and severely stresses its root yield was reduced. 相似文献
7.
Winter beet roots and shoots might be a favorable substrate for biogas production in Central Europe. However, detailed information about the attainable yield of this crop is lacking. Thus, the impact of plant density, genotype and environmental conditions on total dry matter yield of winter beet crops that bolt after winter was investigated. A significant increase of the dry matter yield (esp. shoot) was expected by harvesting the 1st shoot after flowering in June followed by a final harvest of the whole plant in July. In 2009/10, 2010/11 and 2011/12, three series of field trials with (i) 3 target plant densities (148, 246, 370 thousand plants ha−1) and (ii) 3 different sugar beet genotypes were conducted at Göttingen (Lower Saxony, GER) and Kiel (Schleswig-Holstein, GER); (iii), additional field trials with 5 different sugar beet genotypes cultivated at 2 target plant densities (148, 246 thousand plants ha−1) were conducted in 2011/12, to investigate the relation between maximum taproot diameter and the shoot and taproot yield of bolting winter beet. The total dry matter yield considerably varied between 4 and 23 t ha−1. It was predominantly affected by the environment and to a substantially lower extent by plant density. Increasing plant densities increased the total dry matter yield, resulting in a significantly higher total dry matter yield at plant densities ≥300,000 plants ha−1 compared with lower plant densities. Genotypic differences in total dry matter yield were negligibly small. Pruning in June substantially increased the total dry matter yield in July by ca. 8 t ha−1 only in one out of three environments.Final yield in June (without pruning) and July (pruning in June) was positively related with cumulated temperature and global radiation, but also with taproot dry matter yield before winter. The taproot, shoot (1st, 2nd) and total plant yield were positively correlated with maximum taproot diameter.In conclusion, high dry matter yields close to yields of established energy crops grown over winter were obtained with winter beet roots and shoots only under very favorable conditions (climate, single plant size). High yields can be achieved after good pre-winter development. However, for sufficient frost tolerance the taproot size of plants must be rather small. Hence, the cultivation of bolting winter beet under Central European climate conditions has to face a severe conflict of goals concerning winter survival and yield formation. 相似文献
8.
为了研究不同灌溉定额下不同品种(标准型、丰产型和高糖型)糖用甜菜的产量、质量和光合特性的响应,在东北地区甜菜4个生长时期进行了7个滴灌处理水平的试验研究,测定不同处理对标准型、丰产型和高糖型甜菜品种的生长情况、光合特征、产量质量及灌溉效率的响应。结果表明,不同灌溉量对不同类型甜菜生长指标、光合参数及产质量影响不同。标准型和高糖型甜菜品种对其生长性状各指标有利的灌溉定额为320~360 m3/ha,3个品种甜菜叶绿素含量对灌溉定额的最佳响应为300~320 m3/ha。标准甜菜品种随着灌溉量的增加并不利于其进行光合作用,而高糖型与丰产型甜菜品种随灌溉量的增加在叶丛快速生长期对叶片蒸腾速率的影响显著,在320 m3/ha灌溉量处理下光合效率较好。随着灌溉量的增加,标准型甜菜品种根产量增加;当灌溉量达320 m3/ha时,丰产型甜菜品种根产量不再升高而保持平稳、高糖型甜菜品种糖度下降。叶片水分利用效率在生育期前期总体上要高于生育后期,增加灌溉量并不能提高不同类型甜菜品种的灌溉水生产效率。在本研究特定区域内优化不同品种甜菜的灌溉制度可改善甜菜生长和产质量,并为建立甜菜灌溉模型提供理论基础。 相似文献
9.
C. M. Hoffmann 《Journal of Agronomy and Crop Science》2014,200(2):108-118
Plants respond to drought with a restriction of leaf and root growth. The study aimed at analysing the morphological and functional adaptation mechanisms of Beta and Cichorium storage root and leaf forms to limited water supply. Two pot experiments were conducted: (i) with sugar beet, swiss chard, root and leaf chicory at 100 %, 50 % and 30 % water supply, (ii) with sugar beet, fodder beet and swiss chard at 100 % and 30 % water supply. The results indicate that there is no general response mechanism of root and leaf forms to better sustain drought stress. Sugar beet adapted to limited water supply with a marked decrease in the storage root to leaf ratio, indicating in particular a restriction of the predominant sink, while maintaining a very low transpiration coefficient. In contrast, swiss chard, root and leaf chicory kept their storage root to leaf ratio almost constant while adapting the transpiration coefficient. Sucrose storage was inversely related to the accumulation of solutes in the storage root of sugar beet and fodder beet. There is some evidence that the formation of a storage root in sugar beet and root chicory is inhibited by the inability of the plants to establish new sink capacities under drought conditions. 相似文献
10.
Katrin Keipp Birgit W. Hütsch Katrin Ehlers Sven Schubert 《Journal of Agronomy and Crop Science》2020,206(5):517-528
Cultivation of sunflower (Helianthus annuus L.) as one of the most important oil crops is of great importance, especially with focus on drought tolerance under the current climate change. Less precipitation and increasing temperatures lead to more regions with drought problems. In a container experiment, with two different sunflower cultivars, drought stress of 40% water-holding capacity was applied at the seed-filling phase and compared to a control group with regular irrigation to 70% water-holding capacity. Four intermediate harvests during the seed-filling phase and a final harvest at maturity were conducted. During the seed-filling phase, sugar and α-amino-acid concentrations of seeds were not reduced by drought stress. Thus, assimilate availability was sufficient, pointing to no source limitation of seed development. The DNA content of the seeds was also not affected and pointed to no limitation of cell division. However, 40 days after flowering a reduction of cell extension was found. Consequently, a sink limitation occurred under drought stress. At final harvest, seed yield was significantly reduced under drought stress due to a lower single seed weight, whereas seed number per plant was unaffected. Oil concentration was not reduced by drought stress. Thus, oil synthesis did not limit oil yield. Consequently, a reduced oil yield under drought stress during the seed-filling phase was caused by a lower seed weight, which resulted from a decreased cell extension. 相似文献
11.
Remy Manderscheid Andreas Pacholski Hans-Joachim Weigel 《European Journal of Agronomy》2010,32(3):228-239
The increase in atmospheric CO2 concentration [CO2] has been demonstrated to stimulate the growth of C3 crops. However, little information exists about the effect of elevated [CO2] on biomass production of sugar beet, and data from field experiments are lacking. In this study, sugar beet was grown within a crop rotation over two rotation cycles (2001, 2004) at present and elevated [CO2] (375 μl l?1 and 550 μl l?1) in a free air CO2 enrichment (FACE) system and at two levels of nitrogen supply [high (N2), and 50% of high (N1)], in Braunschweig, Germany. The objective of the present study was to determine the CO2 effect on seasonal changes of leaf growth and on final biomass and sugar yield. Shading treatment was included to test whether sugar beet growth is sink limited under elevated [CO2]. CO2 elevation did not affect leaf number but increased individual leaf size in early summer resulting in a faster row closure under both N levels. In late summer CO2 enrichment increased the fraction of senescent leaves under high but not low N supply, which contributed to a negative CO2 effect on leaf area index and canopy chlorophyll content under high N at final harvest. Petioles contained up to 40% water-soluble carbohydrates, which were hardly affected by CO2 but increased by N supply. More N increased biomass production by 21% and 12% in 2001 and 2004, respectively, while beet and sugar yield was not influenced. Concentration of α-amino N in the beet fresh weight was increased under low N and decreased under high N by CO2 enrichment. The CO2 response of total biomass, beet yield and white sugar yield was unaffected by N supply. Averaged over both N levels elevated [CO2] increased total biomass by 7% and 12% in 2001 and 2004, respectively, and white sugar yield by 12% and 13%. The shading treatment in 2004 prevented the decrease in leaf area index under elevated [CO2] and high N in September. Moreover, the CO2 effect on total biomass (24%) and white sugar yield (28%) was doubled as compared to the unshaded conditions. It is concluded that the growth of the storage root of sugar beet is not source but sink limited under elevated [CO2], which minimizes the potential CO2 effect on photosynthesis and beet yield. 相似文献
12.
施钾量对膜下滴灌甜菜光合性能以及对产量和品质的影响 总被引:3,自引:0,他引:3
膜下滴灌技术被广泛应用于内蒙古冷凉干旱地区的甜菜生产中。为探明施钾量对膜下滴灌甜菜光合生理特性和产质量的影响及其适宜钾肥用量, 于2014?2015年在内蒙古凉城县设K2O 0、90、180、270和360 kg hm -25个施肥处理进行了研究。结果表明, 钾素能够提高甜菜的光合性能, 如促进株高、叶面积指数、净光合速率的增加; 施钾肥180、270和360 kg hm -2显著提高了叶丛快速生长期甜菜的净光合速率, 影响净光合速率的最主要因素是RuBPCase活性, 其次是气孔导度, 净光合速率与甜菜产量呈极显著正相关。适宜的钾肥用量有利于块根、叶柄和叶片干重的增加及产量增加, 但施钾过量, 块根干物质分配比例下降, 含糖率下降, 块根干物质分配比例与甜菜含糖率呈显著正相关。施钾量270 kg hm -2时产量最高, 90 kg hm -2时含糖率最高, 当施钾量大于180 kg hm -2时, 块根中K +、Na +含量增加, 大于270 kg hm -2时, 块根中α-氨基酸含量增加, 施钾量180 kg hm -2时产糖量最高。综合考虑施钾量对膜下滴灌甜菜产量和品质的影响, 内蒙古甜菜种植优势区域的钾肥推荐施用量为180 kg hm -2。 相似文献
13.
通过对甜菜在苗期、叶丛繁茂期、块根糖分增长期和糖分积累期的生理所需进行控水灌溉,研究不同灌水量对甜菜产质量的影响,确定少水、多糖、高产的最佳灌水方案,为甜菜节水灌溉提供理论依据,指导甜菜生产科学灌溉。试验设置3312.75、4005.30、4697.85、5390.40、6082.95、6775.50 m3/hm2等6个灌水梯度,在苗期、叶丛繁茂期、块根糖分增长期和糖分积累期分别按各生长期需水比例灌入不同水量,收获时测定甜菜含糖率、产量和产糖量,分析水分利用效率(WUE)和灌溉水分利用效率(IWUE)。结果表明,灌水量对甜菜含糖率、产量和产糖量影响明显,全生育期灌水量为3312.80 m3/hm2时甜菜的产质量处于较低水平,随着灌水量的逐渐增加,甜菜的含糖率、产量和产糖量呈现上升趋势,全生育期灌水量为4697.90 m3/hm2时甜菜的含糖率、块根产量和产糖量均为最高,但当灌水量高于4697.90 m3/hm2时甜菜的含糖率、块根产量和产糖量开始下降,在灌水量为6775.55 m3/hm2时,甜菜的含糖率、块根产量和产糖量均为最低。因此在新疆石河子地区甜菜全生育期灌水7次时,总灌水量在4697.90 m3/hm2,可以使甜菜含糖率、产量和产糖量达到最佳。 相似文献
14.
干旱胁迫是抑制甜菜生长发育和影响产量的重要非生物因素。以耐旱型甜菜种质依安一号(V1)和干旱敏感型种质92011/1-6/1(V2)为试验材料,探讨不同耐旱品种甜菜幼苗光合生理对干旱胁迫的响应。研究了干旱胁迫对甜菜幼苗生长发育、总叶绿素含量和表观光合指标的影响。结果表明,干旱胁迫下2种甜菜幼苗的茎粗、根长、株高、叶鲜重、根鲜重、叶干重和根干重均呈下降趋势,V1下降幅度不明显且各指标降低幅度均小于V2;干旱胁迫降低了2种甜菜幼苗的叶绿素含量,叶绿素含量在第7天降到最低,且V1的含量明显高于V2;干旱胁迫使甜菜幼苗的净光合速率、蒸腾速率、叶片气孔导度和胞间CO2浓度显著下降,V1受到的影响比V2要小。不同耐旱性甜菜品种对干旱胁迫的响应机制存在一定差异,可以进一步分析其抗旱能力,为甜菜的育种、抗逆栽培和稳产提供理论依据。 相似文献
15.
Autumn sown sugar beets (winter beets) are expected to yield markedly higher than spring sown beets. This requires a continuous growth during an extended growing period. So far, bolting‐resistant sugar beet varieties are not available to test winter beets under field conditions in Central Europe. The objective of this study was therefore to analyse yield formation and sugar storage of sugar beet plants during an extended growing period to estimate whether sugar beet has the potential to generate the theoretically expected yield increase. From 2008 to 2012, pot experiments were carried out in the glasshouse with 11 sowing dates spread over the years with sequential harvests. The oldest plants were grown for 859 days (14 242 °Cd). Root fresh matter yield continuously increased till the latest harvest. In contrast, the sugar concentration reached an optimum value between 3400 and 5000 °Cd and then decreased with time. Despite longer growing periods, the number of cambium rings, which are regarded as essential for sugar storage, did not change. This points to an early and genetically fixed determination of the formation of cambium rings. Additionally, the rate of photosynthesis decreased concomitantly with the sugar concentration. In conclusion, there is some evidence that the sugar concentration of the storage root is limited by the sink capacity, which in turn controls the source activity by a feedback regulation of photosynthesis and leaf formation. The dry matter composition of the storage root changed towards lower sugar concentration and concurrent higher concentration of cell wall compounds (marc). The sugar yield still increased beyond a thermal time at which winter beets will probably be harvested in practice. Hence, the theoretical yield increase in autumn sown sugar beets can be realized, provided that the plants show sufficient winter hardiness and bolting resistance. 相似文献
16.
旨在为塔额盆地甜菜生产提质增效提供新途径。在塔额盆地滴灌施肥条件下,以甜菜‘Beta 468’为试验材料开展田间喷施试验,设置4个喷施处理(CK、Un、B、Un+B),喷施处理后测定甜菜生长情况、干物质积累、体内碳氮代谢酶活性及产量和含糖率。叶面喷施烯效唑、硼及烯效唑和复配与CK相比,根长分别增加了7.38%、14.76%和19.68%,总干物质积累增加了10.98%、13.32%和17.60%。块根硝酸还原酶活性提高了12.5%、37.64%和54.07%,蔗糖磷酸合成酶活性提高了37.73%、60.24%和69.31%,蔗糖合成酶活性提高了32.95%、45.43%和21.22%,转化酶活性提高了26.87%、35.79%和33.20%。产量较CK分别增加了10.77%、2.85%和9.97%,含糖率增加了0.47%、0.55%和0.79%,产糖量增加了13.93%、6.21%和15.31%。叶丛期喷施烯效唑和硼复配可促进植株生长、提高甜菜产量和含糖率。 相似文献
17.
Drought tolerance is one of the most important objectives of sugar beet breeding programs in semi-arid regions, particularly
during the last decade. Due to global climate changes and limitations of agricultural irrigation water, varieties with drought
tolerance are taken into consideration in order to avoid yield losses due to drought. In this study, drought tolerance of
76 S1 lines (full-sib families) that had been extracted from a genetically broad base multigerm sugar beet open pollinated population,
were examined. Test crosses were made between the lines as pollinators and a cytoplasmic male sterile (CMS) single cross.
The consequent hybrids along with checks were evaluated during 2007 and 23 more tolerant hybrids during 2008, in two adjacent
experiments under drought stress and non-stress conditions. Drought tolerance indices calculated based on sugar yield, such
as mean productivity (MP), geometric mean productivity (GMP) and stress tolerance index (STI) were used to assess hybrids
responses to drought. The results showed significant genetic differences for root yield and sugar yield under both conditions.
Drought tolerance indices displayed significant genetic variability for sugar yield among the hybrids. Many hybrids were drought
tolerant as compared with the original base population as indicated by their high STI. The estimates of heritability for sugar
yield in stress and non-stress conditions were much close to each other (0.31 and 0.34, respectively). Whereas, for root yield
the heritability estimate in stress condition (0.46) was relatively higher than that in non-stress condition (0.34). Significant
differences were observed among the selected hybrids for root yield and sugar yield, indicating genotypic variability for
pollinator lines derived from the population. There were no significant differences for sugar content. For increasing the
drought tolerance potential in a breeding population and developing drought-tolerant varieties by male parent, the drought-tolerant
lines could be used. 相似文献
18.
Morpho-physiological and molecular analysis were conducted to identify useful root indexes of sugar beet nutrient uptake capacity
and productivity. Root architectural parameters, root elongation rate, sulfate uptake rate and glucose and fructose content
in the root apex, traits involved in the plant response to sulfate stress, were evaluated in 18 sugar beet genotypes characterized
by different root yield. Morpho-physiological traits, determined on 11-day-old seedlings grown in hydroponics under sulfate
deprivation, showed variations from 59 to 197% and were significantly correlated (P < 0.01) with root yield. Under field conditions, the highest root yield genotype (L18), which has the highest root phenotypic
values following sulfate shortage, also showed the greatest root length density and leaf relative water content, with respect
to the lowest root yield genotype (L01). Bulk segregant analysis based on AFLP analysis, done on a segregating progeny obtained
from the cross between the two lines L01 × L18, allowed the identification of two AFLP markers associated to the root elongation
rate parameter that showed the highest variation among all the analyzed root traits. The genetic diversity of root adaptive
traits and the use of marker-assisted selection aimed at increasing sugar yield under water and nutrient stress in sugar beet
breeding programmes are discussed. 相似文献
19.
膜下滴灌条件下高产甜菜灌溉的生理指标 总被引:1,自引:0,他引:1
甜菜是我国重要的糖料作物,其生物产量高,需水量大,合理灌溉是节约用水、提高产量的有效措施之一。本试验连续两年研究了内蒙古半干旱地区膜下滴灌条件下,不同灌水量甜菜块根产量与叶面积指数、净光合速率、蒸腾速率、叶水势、土壤含水量和耗水量之间的关系,以及不同灌水量对甜菜产量和水分利用效率的影响。结果表明,高产甜菜的叶面积指数在叶丛快速生长期大于7.37,在块根糖分增长期和糖分积累期分别为6.08~6.51和4.19~5.57,在叶丛快速生长期、块根糖分增长期和糖分积累期叶水势分别为–0.09~–0.22、–0.18~–0.39和–0.26~–0.48 MPa,净光合速率分别为21.28~28.23、21.90~28.75和22.06~26.58μmol m–2 s–1,蒸腾速率在叶丛快速生长期和块根糖分增长期分别为9.36~10.21 mmol m–2 s–1和6.37~7.73 mmol m–2 s–1,在糖分积累期大于4.69 mmol m–2 s–1,耗水量分别为140.15~312.78、44.93~200.45和56.32~113.06 mm。甜菜产量、产糖量、水分利用效率均高的合理灌溉量,在丰雨年份(生育期降雨量500 mm)为1350 m3 hm–2,在少雨年份(生育期降雨量300 mm)为1800 m3 hm–2,为甜菜节水灌溉提供了理论依据和生理指标。 相似文献
20.
Remote sensing and vegetation indices can be used to characterize the canopy of crops with a non‐destructive method on a large scale. Leaf area formation of sugar beet in early summer is the most important variable for crop growth models. This study aimed at estimating whether differences in leaf area development of sugar beet resulting from different agronomic practices can be determined with remote sensing. The relationship between the normalized difference vegetation index (NDVI) and leaf area index (LAI) during the season and yield of the storage root in autumn was studied in six field trials in 2001 and nine field trials in 2002. The vegetation index NDVI gave a good impression of differences in leaf development of sugar beet in early summer. LAI increased with increasing NDVI up to an NDVI of 0.65. Above that the NDVI did not respond as distinctly to treatments as the LAI. An exponential function was developed to calculate sugar beet LAI from NDVI, so that remote sensing data can be used as input variable for crop growth models. The yield of the storage root in autumn did not show any relationship to LAI or NDVI during the season, regardless of whether it was measured in June or September. Therefore, it seems to be necessary to combine NDVI data with crop growth models to forecast a potential sugar beet yield in autumn. For this purpose the formula presented is a valuable tool. 相似文献