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1.
以钾高效高潜基因型HG103和低效低潜基因型LG122为材料,在盆栽条件下研究了钾对不同棉花基因型叶片解剖结构的影响。结果显示:花铃期施钾条件下HG103上部叶主叶脉的上、下表皮细胞排列较LG122紧密和整齐,而下部叶片则相反;缺钾后HG103上部叶主叶脉比LG122发育得好;HG103叶脉维管束木质部具有较多导管数,利于养分和水分等的运输,而LG122木质部导管数相对较少;HG103上部叶叶脉的韧皮部比LG122较为发达,利于光合产物运输。花铃期施钾条件下HG103上部叶的叶肉细胞结构与LG122差别不大,下部叶的栅栏组织则没有LG122排列的整齐。缺钾时,HG103上部叶叶肉的上表皮细胞比LG122排列的较为整齐,栅栏组织和海绵组织形状较规则;而下部叶LG122栅栏组织和海绵组织比HG103分化得好。 相似文献
2.
嫁接对不同棉花基因型钾效率的影响 总被引:1,自引:0,他引:1
采用全生育期土培盆栽试验,在研究2个棉花基因型钾吸收效率和利用效率的基础上,对未嫁接和经嫁接的自根苗(接穗和砧木为同一基因型)处理的棉花干物质和钾的积累、分配进行比较。结果表明:自根苗植株与未嫁接植株相比,不同棉花基因型在不同钾水平下干物质和钾的积累及分配不同。高效基因型103经过嫁接后营养器官中的干物质和钾比例增加,生殖器官中的干物质和钾减少,产量和钾利用指数下降;低效基因型122经过嫁接后营养器官中的干物质和钾比例减少,生殖器官中的干物质和钾增加,产量和钾利用指数升高。吸收效率因钾水平而异,高效基因型103嫁接后施钾时吸收效率降低,缺钾时升高;而低效基因型122嫁接后施钾时吸收效率升高,缺钾时降低。嫁接对不同棉花基因型产生的效应不同,通过嫁接使不同棉花基因型物质分配趋于平衡。 相似文献
3.
Potassium (K) deficiency is one of the main limiting factors in cotton (Gossypium hirsutum L.) production. To study the mechanism of high K‐use efficiency of cotton, a pot experiment was conducted. The experiment consisted of two cotton genotypes differing in K‐use efficiency (H103 and L122) and two K‐application levels (K0: 0 g (kg soil)–1; K1: 0.40 g (kg soil)–1). Root‐hair density and length, partitioning of biomass and K in various organs, as well as K‐use efficiency of the two cotton genotypes were examined. The results show that there was no significant difference in K uptake between the two genotypes at both treatments, although the genotype H103 (high K‐use efficiency) exhibited markedly higher root‐hair density than genotype L122 in the K1 treatment. Correlation analysis indicates that neither root‐hair density nor root‐hair length was correlated with plant K uptake. Furthermore, the boll biomass of genotype H103 was significantly higher than that of genotype L122 in both treatments, and the K accumulation in bolls of genotype H103 was 39%–48% higher than that of genotype L122. On the other hand, the litter index (LI) and the litter K‐partitioning index (LKPI) of genotype H103 were 14%–21% and 22%–27% lower than that of genotype L122. Lastly, the K‐use efficiency of total plant (KUE‐P) of genotype H103 was comparable with that of genotype L122 in both treatments, but the K‐use efficiency in boll yield (KUE‐B) of genotype H103 was 24% and 41% higher than that of genotype L122 in K0 and K1 treatments. Pearson correlation analysis indicated that KUE‐P was positively correlated with BKPI and negatively correlated with LKPI, while KUE‐B was positively correlated with BKPI and boll‐harvest index (HIB), and negatively correlated with LKPI. It is concluded that there were no pronounced effects of root‐hair traits on plant K uptake of the two genotypes. The difference in K‐use efficiency was attributed to different patterns of biomass and K partitioning rather than difference in K uptake of the two genotypes. 相似文献
4.
It is essential to produce optimal crop yields while reducing adverse environmental impacts of overfertilization. Therefore, nutrient‐efficient plants may play a major role in improving the efficiency of fertilizer use whilst increasing crop yields. This field trial was conducted to study the differences on absorption and utilization of nitrogen (N), phosphorus (P), and potassium (K) of K‐efficient cotton genotype 103 and K‐inefficient cotton (Gossypium hirsutum L.) genotype 122 and their environmental and economic effects. The results show that seed cotton yield was significantly different between K‐efficient cotton genotype 103 and K‐inefficient cotton genotype 122; the yields of genotype 103 were 39.2%, 33.8%, and 25.0% higher than those of genotype 122 with no K fertilizer (K0), 112 kg K ha–1 K (K1), and 224 kg K ha–1 (K2), respectively. Even when no K fertilizer was applied, the yield of genotype 103 was still 7.9% higher than the yield of genotype 122 at the highest K level (K2). Further economic benefit analysis revealed that the value cost ratio (VCR) of genotype 103 was significantly higher than 122 at K0 and K1, and harvest index (HI) of genotype 103 was significantly higher than that of genotype 122 at all three K levels. In addition, when fertilized with K, partial factor productivity of applied K (PFPK) of genotype 103 was dramatically higher than that of genotype 122, demonstrating that genotype 103 had stronger ability to utilize K. Besides, the N‐ and P‐use efficiencies of genotype 103 were also higher than those of genotype 122. It is concluded that: (1) genotype 103 gives better profit than genotype 122 and (2) genotype 103 uses fertilizer more efficiently and reduced fertilizer inputs will alleviate environmental risks. 相似文献
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6.
【目的】钾是植物生长发育所必需的营养元素之一,缺钾影响棉花的生长。钠与钾有一些相同的生理功能,钠钾替代和协同作用是提高作物钾效率有效途径之一。研究钠钾替代对不同基因型棉花钾效率的影响,旨在为生产中科学高效利用钾肥提供依据。【方法】于2013~2014年在华中农业大学利用盆栽试验,筛选并获得了钾高效高增产潜力棉花基因型103和钾低效低增产潜力棉花基因型122为试验材料,采用营养液培养对不同K+、Na+浓度处理条件下棉花苗期农艺性状(株高、根长和叶片数)、干物质积累与分配、各部位(根、茎、叶和柄)钾钠含量和钾钠积累量等进行了研究,探讨了钠钾替代作用对其钾素利用效率的影响。【结果】缺钾的条件下,施钠增加了两个基因型的根长,且103增加的幅度大于122;增加了103和122各部位干重和根冠比,而减少了根和茎的钾含量,对各部位钾积累量影响不明显,施钠还能显著提高基因型棉花103的钾利用效率,其为不施钠时的1.37倍。另外,适钾的条件下施钠,两个基因型的根长都有所增加,且103增加的幅度大于122;103和122各部位干重和总干重都显著增加,但二者根和叶钾含量显著降低,除了叶和柄其他各个部位的钾积累量都不同程度的提高;同时,103和122的钾利用效率均增加,103增加了28%,大于122的19%。此外,钾钠交互作用对根长和株高的相对生长速率,各部位干物重和根、叶中钾、钠含量和积累量以及全株钾利用效率都有显著影响。【结论】无论是否施钾、施钠均能增加两个基因型棉花的根长,通过促进根系的伸长来提高棉花对钾的吸收和生物量的积累。缺钾时施钠显著增加了103的钾效率,且适钾时施钠高效基因型103的钾效率增加幅度大于低效基因型122,表明钠钾替代和协同效应对钾高效基因型103比低效基因型122更显著。 相似文献
7.
不同基因型棉花苗期钾效率差异及其机制的研究 总被引:13,自引:4,他引:13
用营养液培养研究了103、138、163、1651、22和169等6个棉花基因型苗期钾效率差异及其初步机制。根据不同基因型钾效率系数和增长潜力的差异,区分为高效高潜(103、138)、高效低潜(163、165)、低效高潜(122)和低效低潜(169)基因型。在钾胁迫时,1031、38长势较好,单株干物重最大,而钾含量最低,它们能以较低钾含量构建较多的生物量,因此对钾的利用率大;由于其干物质冠根比大,因而能使较少的根系物质维持较多的地上部生长;与此相应,其单株钾积累量较大,且地上部钾积累量占较大比重,表明其吸收和转运钾素的能力较强;其叶绿素含量是上部叶高于下部叶,且二者差值较大,从而较好地促进上部叶的生理功能。而122、169则正好相反,缺钾时它们具有较高的钾含量,干物重却最小,其中169干物重仅为103的43.93%,因而钾积累量也最少,其吸收、积累和利用钾的能力弱。163、165的单株干物重、增长潜力以及地上部钾积累量比重均较低,其吸收和转运钾的能力属中低水平。 相似文献
8.
Yanshu Hao Jing Lei Qiaolan Wang Lishu Wu 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2013,63(1):45-53
As a macroelement to plant, potassium (K) absorption mechanism has been widely studied. However, as for cotton genotypes with different K efficiency, how they related to the absorption patterns under K starvation is not fully understood. In this hydroponic experiment, plants were grown at different K levels: low (K1, 2 mg/L) and adequate K level (K2, 20 mg/L) for 2 weeks. K+ absorption kinetic parameters were got by Michaelis–Menten equation. By applying K channel-blocking agent, tetraethylammonium and protein modifying reagent N-ethylmaleimide, we evaluated the differences in K absorption mechanisms for two typical cotton genotypes (K-efficient genotype 103 and K-inefficient genotype 122). Results showed that higher affinity to K+ and better root formation of genotype 103 resulting in better adaptation in low-K+ condition, whether grown in low or adequate K+ environment. Further study with K+ absorption inhibitors suggested the two genotypes grown in low-K+ environment absorbed K+ mainly by high-affinity K+ absorption systems, and for seedlings grown in adequate K condition, genotype 103 absorbed K+ with both K channels and high-affinity proton and mainly by high-affinity K channels, while genotype 122 absorbed K+ by K channels. These results indicated that the low-K condition could induce higher affinity to absorb K+, and the two cottons with different K efficiency mainly due to different low-K adaptation and absorb K+ with different patterns. This could provide a possible theory for the selection of K-efficient varieties. 相似文献
9.
钾高效基因型棉花的筛选及其生理机制的研究 总被引:3,自引:0,他引:3
通过营养液培养,设缺K和适K处理,进行棉花苗期培养,以苗期干物质的K效率系数(-K/ K)评价K效率差异,从86个不同系谱的棉花品种中分次逐步筛选,获得4个候选品种.对候选品种进行全生育期土培试验,设施K和不施K处理,获得皮棉产量,以皮棉产量的K效率系数(-K/ K)来反映品种间的K效率差异,确定103为K高效高潜力基因型,122为K低效低潜力基因型,163和165为K高效低潜力基因型.103具有较强的吸收土壤速效K、活化土壤缓效K的能力,并以较低的K含量往繁殖器官运输分配,建成较多的子棉和皮棉,这可能是其K高效的机制之一. 相似文献
10.
Yanshu Hao Jing Lei Xiuwen Wu Lishu Wu 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2016,66(2):170-177
Potassium (K) is an essential macronutrient for plant growth and development. Plant growth and development can be seriously affected by K deficiency. However, plants with different K efficiencies behave differently. It is still not fully understood how plants with higher K efficiency could maintain better growth in a low K environment and what is the relationship between K recycling and photosynthesis metabolism. The aim of this study was to investigate whether the difference in K re-translocation and photosynthesis transportation can explain genotype differences in K efficiency between K-efficient genotype 103 and K-inefficient genotype 122. Results of this study showed that the dry matter accumulation of genotype 122 decreased much more than that of genotype 103 affected by K deficiency environment. Root growth of the two genotypes was inhibited by K deficiency, but genotype 122 was affected more than genotype 103. Using the K utilization index as an evaluation factor for K efficiency, it was found that genotype 103 was significantly higher than genotype 122. Potassium affected the K distribution in plants for both the genotypes. Potassium was distributed more to the stem and leafstalk in a normal K environment whereas it was more to the leaf and root in a low K environment, especially for genotype 103. Potassium also affected photosynthetic products’ distribution. The leaf of genotype 122 accumulated most of its photosynthetic product while genotype 103 had better ability to transport it into the root to maintain better growth under a K-deficient environment. Results of this study indicated that more K recycling into the root and more efficient transport of the photosynthetic product into the root contribute to better root growth and therefore increased tolerance to K deficiency. 相似文献
11.
Cultivated tetraploid Gossypium hirsutum L. (Malvaceae) cotton has been characterized as having one flower at a primordia. In a strain (CSH-13) of Gossypium hirsutum cotton, four plants out of 103 had two to three double bolls or twin bolls/plant during 2003–2004 crop season at CICR regional station, Sirsa, Haryana, India. Progeny evaluation in 2004 and 2005 crop seasons indicated that plants raised from seeds harvested from double bolls/twin bolls produced plants bearing double bolls only and plant progeny raised from the seed of single bolls from these mutant plants produced two to three double bolls per plant similar to the parent. Progeny testing revealed that double boll formation is the result of spontaneous mutation and environment does not influence its expression. The mutant is early in maturity by 10–15 days, naked seeded and possesses comparable agronomic characters with normal plants. Another spontaneous mutant of Gossypium hirsutum having more than three appendages originating from primordia.: four bolls one leaf, three bolls one leaf, two bolls two leaves, one boll three leaves were obtained from the population of CISV-13 strain in crop season 2003. These appendage groups have been described as bicolor unit by Clemens Bayer, [Zur Infloreszenzmorphologie der Malvales. Dissertations Botany 212 (1994)] and cluster mutant by Russell and Luther [J Cott Sci 6 (2002) 115]. One to three bolls in a cluster or bicolor unit were observed without formation of seeds and lint. About one-third of the total bolls on the mutant plant were of this type. In progeny testing during 2004 and 2005 crop seasons, this mutant produced plants exclusively with more than three appendages revealing that plants identified in 2003 were due to spontaneous mutation. This mutant was also early and naked seeded. Many of the other characters of the mutant plants were comparable with the wild type plants of the strain. Both the mutants were observed having economic impact due to their better yielding ability as compare to respective parents. 相似文献
12.
The effect of potassium (K) supply on dry matter accumulation and partitioning of biomass between different among parts of
cotton (Gossypium hirsutum L.) was determined under irrigated conditions. The treatments were four cotton cultivars (CIM-448, CIM-1100, Karishma, and
S-12), four K rates (0, 62.5, 125, and 250 kg K ha−1), and two K-fertilizer sources (K2SO4, KCl). Sequential harvests were collected at four stages of growth, viz first flower, peak flowering, first boll split, and
maturity. The dry weights (DW) of vegetative and reproductive organs were determined. Maximum total DW was obtained at 125 days
after planting, and then it declined because of leaf senescence at maturity. Cultivars differed significantly among themselves
in the production of total DW and its partitioning between different organs. The addition of K fertilizer increased DW substantially
at various stages of growth. Potassium fertilizer stimulated cotton plant to translocate resources towards reproductive organs
rather than vegetative organs. Crop receiving 250 kg K ha−1 allocated 77% more dry matter into reproductive organs. The K-sources produced a little effect on the allocation of DW in
various parts of the plant. Maximum reproductive–vegetative ratio (RVR) was maintained by cv CIM-448 and minimum in cv CIM-1100.
Data showed that a shift in DW allocation into reproductive organs was dependent upon sustained supply of K+ throughout the season. There were positive significant correlations (0.86, 0.71, and 0.90) between seed cotton yield and
total DW, vegetative DW, and reproductive DW, respectively. 相似文献
13.
Xiao Wang Ibrahim Mohamed Maha Ali Mohamed H. H. Abbas Ghulam Mustafa Shah Fang Chen 《植物养料与土壤学杂志》2019,182(1):72-81
A rhizobox experiment was conducted to compare the differences of soil potassium (K) distribution and absorption between two cotton (Gossypium hirsutum L.) genotypes under drought and K‐deficit conditions. Treatments included two levels of water (drought and optimum soil moisture: 25% and 35% volumetric water content) and K fertilizer rates (0 and 0.48 g potash kg?1 soil) applied to two cotton genotypes (namely HEG and LEG). Both the genotypes showed significant differences in total K accumulation without exogenous K addition. After absorption, soil content of the readily available potassium (RAK) decreased rapidly. This promoted the conversion of the mineral K into slowly available potassium (SAK). Drought significantly decreased the cotton growth and K use efficiency, and thereby reduced the effect of K fertilizer. Consequantly, the contents of RAK and SAK were greatly increased. However, K bioavailability was decreased under water stress conditions. Differences in root parameters and soil microorganisms between two cotton genotypes were significantly increased and had marked relations with available soil K contents. This study provides important information for understanding the mechanism of K use efficiency, especially under water and K stress. 相似文献
14.
以大铃、中铃和小铃3个不同铃重棉花基因型为材料,通过在盛花期测定棉株中部主茎和果枝叶面积及叶面积指数,并用14CO2饲喂中部主茎叶,研究了14CO2同化物在棉株不同层次"铃-叶系统"中的分配特征。结果表明,盛花期中部主茎和果枝单叶面积与铃重呈正相关。小铃基因型棉花群体盛花期叶面积指数最大;大铃基因型棉花蕾铃比中、小铃基因型表现出更强的库活性。主茎叶片产生的同化物除主要输送到对应的果枝外,还向上部、下部的库器官及主茎生长点输送;而流向其对应果枝的同化物,主要供应第一果节蕾铃。 相似文献
15.
施钾对不同基因型棉花光合特性及产量和品质的影响 总被引:7,自引:3,他引:7
在田间条件下,研究了施钾对抗虫杂交棉中棉所38、抗虫棉新棉33B、常规棉中棉所12光合特性和产量及品质的影响。结果表明,与不施钾相比,不同基因型棉花施氯化钾225.kg/hm2,棉花叶面积指数(LAI),叶绿素荧光动力学参数PSⅡ最大光化学量子效率(Fv/Fm)、PSⅡ潜在光化学活性(Fv/Fo)、PSⅡ实际光化学效率(ФPSⅡ),叶片净光合速率(Pn)、气孔导度(Gs),棉花干物重及分配到生殖器官的比例,棉花总成铃数、铃重和衣分均有不同程度提高;中棉所38、新棉33B和中棉所12皮棉产量分别增加13.60%、10.66%和4.21%;棉纤维2.5%跨距长度、比强度、马克隆值和纤维整齐度等品质也得到改善。中棉所38和新棉33B比中棉所12施钾的效果更好,生产上应优先给抗虫杂交棉和抗虫棉品种施用钾肥。 相似文献
16.
不同早、中熟基因型棉花品种的干物质积累及养分吸收规律研究 总被引:1,自引:0,他引:1
利用Logistic方程对2个早熟棉品种(中36、中50)和2个中熟品种(中41、鲁28)的单株干物质积累、N、P2O5、K2O吸收动态进行模拟研究,结果表明,早熟品种与中熟品种吸收积累养分的高峰期均在开花至吐絮期。2个早熟棉品种单株干物质质量、N、K2O积累快速增长持续时间短于中熟品种,P2O5积累快速增长持续时间略长于中熟品种。早熟品种在吐絮至收获阶段,干物质积累及养分吸收占全生育期的比例高于中熟品种,成熟单株对P2O5、K2O的吸收比例高于中熟品种,在肥料配比上可适度加大磷钾肥比例。 相似文献
17.
Fuqiang Yang Gangwei Wang Zhiyong Zhang A. Egrinya Eneji Liusheng Duan Zhaohu Li 《Journal of plant nutrition》2013,36(1):83-97
Genotypic differences in potassium (K) uptake and utilization were compared for eight cotton cultivars in growth chamber and field experiments. Four of the cultivars (‘SGK3’, ‘SCRC18’, ‘SCRC21’ and ‘SCRC22’) typically produce lower dry mass and the other four (‘Nannong8’, ‘Xiangza2’, ‘Xinluzao12’ and ‘Xiangza3’) produce greater dry mass in K-deficient solution (0.02 mM). The mean dry weight of seedlings (five-leaf stage) of cultivars with greater biomass was 155% higher than that of cultivars with lower biomass yield under K deficiency. However, all the genotypes had similar dry matter yields in K-sufficient solution (2.5 mM). Thus, the four cultivars with superior biomass yield under low K medium may be described as K efficient cultivars while the inferior cultivars may be described as K inefficient. Although seeds of the studied cultivars originated from different research institutes or seed companies, there were little differences in seed K content among them, irrespective of their K efficiency. Consequently, there were no significant differences in K accumulation in seedlings (4 d after germination in a K-free sand medium) just before transferring to nutrient solutions. However, the K efficient genotypes, on average, accumulated twice as much K at 21 d after transferring to K-deficient solution (0.02 mM). A much larger root system as well as a slightly higher uptake rate (K uptake per unit of root dry weight) may have contributed to the higher net K uptake by the K efficient cultivars. In addition, the K efficiency ratio (dry mass produced per unit of K accumulated) and K utilization efficiency (dry mass produced per unit of K concentration) of the K efficient cultivars exceeded those of the K inefficient genotypes by 29% and 234%, respectively, under K deficiency. On average, the K efficient cultivars produced 59% more potential economic yield (dry weight of all reproductive organs) under field conditions even with available soil K at obviously deficient level (60 mg kg?1). We noted especially that the four K inefficient cultivars studied were all transgenic insect-resistant cotton, suggesting that the introduction of foreign genes (Bt and CpTI) may affect the K use efficiency of cotton. 相似文献
18.
《Communications in Soil Science and Plant Analysis》2012,43(15):1984-1993
Cotton (Gossypium hirsutum L.) is one of the most important cash crops in the world, and potassium (K) is an important limiting factor for cotton farming. Therefore, it is critical to improve K-use efficiency by selecting or breeding cotton genotypes with high K-use efficiency. Through a pot experiment with low-K soil, this article documentes the differences in vessel element anatomy and root hair traits between two cotton genotypes with different K-use efficiencies at both seedling and boll stages. Experimental results showed that at the seedling stage both frequency and length of root hair in the genotype with high K-use efficiency were significantly greater than those of the genotype with low K-use efficiency, but the frequency and diameter of vessels were not significantly different between the two genotypes. In the boll stage, the vessel frequencies in root, stem, petiole, and carpophore; root hair frequency, and length of high K-use-efficiency genotype were all significantly greater than those of the low K-use-efficiency genotype. The denser and longer root hairs were often found and accompanied by thicker vessel elements in the genotype with high K-use efficiency. This means the genotype had greater nutrient uptake and transportation capacity. The root hairs, vessel elements in root, stem, petiole, and carpophore, formed a complete system for nutrient uptake and translocation. The results from this study provide valuable information for the breeding of high K-use-efficiency cotton. 相似文献
19.
《Journal of plant nutrition》2013,36(6):1023-1039
Abstract A field experiment was conducted to assess the effectiveness of fruiting positions along sympodia under varying levels and sources of potassium (K) fertilizer on field-grown cotton in an arid environment. Treatments consisted of four rates of K (0, 62.5, 125.0, 250.0 kg K ha? 1) and two types of K (K2SO4 and KCl). Cotton cultivar S-12 (Gossypium hirsutum L.) was used as a test crop. Plant mapping data showed that the total number of fruiting positions, number of intact fruit on sympodia/monopodia, and percent of bolls per position on sympodia differed greatly under different doses of K fertilizer. The percentage of fruit retention was markedly improved under increasing doses of K fertilizer as compared with the K-unfertilized treatment. The percent survival of harvestable bolls for the first five positions along sympodia at the end of the season was 30%, 25%, 18%, 13%, and 8%, respectively. Potassium fertilization stimulated cotton crop in lengthening sympodial branches and retaining more fruit on the first three positions and also at the bottom of the plant during the early reproductive phase. The fruiting pattern was 2–3 and 6–7 d vertical and horizontal fruiting interval, respectively. 相似文献
20.
A greenhouse hydroponic experiment was conducted to study the effects of cadmium (Cd; 0, 0.1, 1.0, 10 μM in nutrient solution) on yield and yield components as well as Cd concentration and accumulation in three cotton genotypes (Simian 3, Zhongmian 16, Zhongmian 16–2). The results showed that Cd concentration in different organs increased with increasing Cd levels in the nutrient solution in the following order: root > petiole > xylem > fruiting branch, leaf > phloem in vegetative organs and seed coat, seed nut > boll shell > fiber in reproductive organs. There were significant genotypic differences in functional leaf and petiole Cd concentrations at 1 and 10 μM Cd treatments, with the cultivar Simian 3 showing higher Cd concentrations and greater reductions in lint yield than the other two genotypes. 相似文献