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1.
为研究富贵籽成花的影响因素,探明其花芽分化与环境主要因素温度和光照的关系,以1.5~2年生盆栽富贵籽为试验材料,采用不同的温度、光周期和光照强度进行试验研究。结果表明,温度对富贵籽的花芽分化起决定性的作用,是影响富贵籽成花的主要因素,20~25℃处理下的富贵籽植株可以完成花芽分化和成花,而10℃处理的植株一直处于营养生长状态而未能花芽分化。光照对富贵籽的成花不起主导作用,在营养生长充实的条件下,无论是长日照还是短日照,只要温度合适富贵籽即可进行花芽分化,说明光周期对富贵籽的花芽分化不起作用,但合适的光照强度有利于其生长发育。 相似文献
2.
R. Keeve G. H. J. Krüger H. L. Loubser J. A. M. Van Der Mey 《Journal of Agronomy and Crop Science》1999,183(4):217-223
An experiment to determine the effect of temperature and photoperiod on Lupinus albus under controlled environmental conditions was carried out, using the three Lupinus albus genotypes 'Tifwhite', 'Esta' and 'Kiev', and three temperature (10/20, 18/28 and 20 °C continuously) and two photoperiod (8 and 16 h daylength) regimes, in all combinations. Half of the seeds were vernalized for 21 days at 4 °C to alleviate the obligate vernalization requirement of Tifwhite. Although Esta and Kiev do not have obligate vernalization requirements, they were influenced by this vernalization period. Observations included the duration of the period from planting to seedling emergence, the duration of the period from planting to the beginning of flowering and the duration of flowering. The vernalization treatment accelerated plant development in all genotypes. The period from planting to emergence was shorter under the higher temperature regime. For all genotypes, the period from planting to flowering was shorter under the longer photoperiod, the same trend as would be expected for long-day plants. Duration of flowering periods were, in contrast to pre-flowering periods, shorter for all genotypes at cooler temperatures. The results of this study confirm that photoperiod does contribute to the growth period from planting to flowering in L. albus and that this species does behave as a long-day plant. 相似文献
3.
The influence of flowering time genes on environmental adaptability in European wheats 总被引:16,自引:0,他引:16
Anthony John Worland 《Euphytica》1996,89(1):49-57
Summary In order to obtain high levels of environmental adaptability in wheat varieties it is essential they flower at times appropriate to particular environmental conditions. The influence of three distinct genetic systems that together determine time of flowering is reviewed here.Vernalization genes are seen to be particularly important to winter wheats for their direct or indirect effects on winter hardiness. Vernalization genes play a minor role in determining flowering time in autumn sown winter wheats but insensitivity is essential if spring sown wheats are to flower.Day length sensitive photoperiod genes play a major role in determining flowering time and adaptability of autumn sown wheats. Insensitivity can promote yield advantages of over 35% in Southern European environments. 15% in Central Europe and offers benefits even in the UK. At present only a single allele of Ppd1 appears to have been introduced into commercial European wheat varieties. The merits of alternative Ppd1 alleles or different loci are discussed.The influence of earliness per se genes that determine flowering time independently of environmental stimuli is less well documented than the effect of photoperiod and vernalization genes. It is likely that genes on chromosomes belonging to groups 2, 3, 4, 6 and 7 may act to modify flowering time independently of environmental stimuli probably by determining numbers of vegetative and floral primordia being initiated or the rate of initiation of the primordia. Earliness per se genes appear to be widespread in European wheats and play a significant role in determining the exact time plants flower. 相似文献
4.
Summary Forty strains of mungbeans, including all of the entries in the 1st and 2nd International Mungbean Nurseries (IMN), were grown in plant growth chambers in photoperiods of 12, 13, 14, 15, and 16 hours and mean temperatures of 18, 23, and 28°C. Results show that (1) mungbean strains differ in their flowering response to photoperiod and to mean temperature; (2) increasing the photoperiod of reducing the mean temperature delayed flowering, the amount of delay varied with the strain: (3) variations in mean temperature may alter the effect of the photoperiod on flowering in particular strains. Twenty-five strains which flowered in all photoperiod-temperature treatments could be divided into four groups, each group being successively later in flowering. The remaining 15 strains could be divided into four groups, according to their failure to flower within 105 days in specific photoperiod-temperature treatments. Flowering response in the growth chamber is useful in explaining flowering response in the 2nd IMN at three locations varying from 14°N to 49°N latitude.Contribution No 7516 from the Missouri Agricultural Experiment Station. 相似文献
5.
以光周期处理与分期播种试验综合鉴定大豆品种的光温反应 总被引:7,自引:1,他引:6
设置短日照(12 h)和长日照(16 h)两种光周期处理,并以春播模拟低温、夏播模拟高温条件,形成长日+低温、长日+高温、短日+低温、短日+高温4种光温组合。2007年对近年育成的10个北方春大豆[Glycine max (L.) Merr.]品种(系)和18个黄淮海夏大豆品种(系)进行了光温反应特性鉴定。2008年对50份材料进行了光周期反应鉴定。结果表明,不论在低温(春播)还是高温(夏播)条件下,短日照均加快大豆的发育进程,导致开花提前;不论在长日照还是短日照条件下,高温均减少出苗至初花的日数。光周期和温度对大豆的发育存在明显的互作,随着温度的升高,短日照促进大豆发育的效应有所加强;随着日照的缩短,高温加快发育的作用也有所增大。供试大豆品种生态类型在光周期反应敏感度(PRS)、温度反应敏感度(TRS)及光温综合反应敏感度(PTCRS)等方面均存在显著差异。北方春大豆品种的上述3个指标均小于黄淮海夏大豆品种,但前者在不同光照条件下的温度反应敏感度差值和在不同温度条件下的光周期反应敏感度差值均较后者高,说明北方春大豆品种光温互作效应较强。 相似文献
6.
Mohammed Mitache Aziz Baidani Chafika Houasli Khadija Khouakhi Bouchaib Bencharki Omar Idrissi 《Plant Breeding》2023,142(4):463-476
The use of high-performing varieties could contribute to increase food legume production and meet the population demand. However, the long process of conventional breeding is a serious limitation that needs further acceleration of genetic improvement. Speed breeding based on extended photoperiod is one of the techniques that allows rapid generation turnover by accelerating the plant life cycle. The present study focused on optimizing the duration of extended photoperiod for lentil, chickpea and faba bean in a growth chamber with light-emitting diode (LED) light sources. Significant differences in growth rate, biomass production, phenology, physiology, plant injury and yield components were observed depending on light phase durations (22, 18 and 14 h). Twenty-two hours of light resulted in earlier flowering and maturity, but higher stress symptoms than the other two light treatments. However, vegetative development was almost normal with limited stress under 14 h of light, but late flowering and maturity. Interestingly, good plant establishment with limited stress and shorter vegetative cycle was observed under 18 h of light. Therefore, a photoperiod of 18 h of light/6 h of darkness could be advised for a rapid breeding protocol. 相似文献
7.
The heading characters and morphological traits of two partial sets of wheat–barley disomic addition lines, namely Mv9kr1/Igri and Asakaze/Manas, were evaluated under controlled environmental conditions in a phytotron under long-day, short-day and non-vernalised conditions and in field-sown experiments. The winter barley chromosome additions significantly influenced the flowering time of wheat both in the controlled environment test and under field-sown conditions. Of all the barley addition lines, the effect of the 4H and 7H additions was the most characteristic. The 7H addition lines were the earliest in both cultivar combinations in each treatment. In the Mv9kr1/Igri combination the 4H addition was the latest under all the environmental conditions. In the Asakaze/Manas combination 4H addition was the latest under short-day and long-day illumination in the phytotron but the 6H addition was the latest without vernalisation and in the field in 2012. There was 12 and 11 days difference between the flowering times of the 7H and 4H Mv9kr1/Igri and Asakaze/Manas addition lines in the field in 2012, which increased to 52 and 44 days under short-day illumination in the phytotron. In the winter wheat background, the addition of 2H carrying the photoperiod sensitivity gene Ppd-H1 decreased the flowering time under the short photoperiod regime, but had a very strong delaying effect under field-grown conditions. Considering the yield components under field conditions, 4H was the most fertile of the addition lines, while 7H showed the highest tillering capacity, and Igri 3H had good tillering capacity and the highest number of seeds per plant. 相似文献
8.
T. Han C. Wu R. S. Mentreddy J. Zhao X. Xu J. Gai 《Journal of Agronomy and Crop Science》2005,191(4):255-262
Pre-flowering photoperiod effects on floral initiation, flowering time and yield components of various crops have been well studied, but the post-flowering photoperiod effects on major field crops are not clearly understood. A controlled environment study was carried out using six long-day (LD) crops, flax, sugar beet, broad bean, triticale, wheat, and rapeseed, and seven short-day (SD) crops including Adzuki bean, potato, rice, peanut, mungbean, cotton and corn with a major objective of evaluating the post-flowering photoperiod effects on their reproductive development and yield components. There were significant inter- and intra-specific differences in their response to post-flowering photoperiod treatments. The effects of short days on LD crops were similar to LD effects on SD crops. The post-flowering duration was prolonged by short photoperiod in LD crops and long photoperiod in SD crops. There was, however, significant genotypic variation within a species for such effects. The post-flowering LD treatment caused abscission of flowers and pods and the resumption of vegetative growth in Adzuki bean. The post-flowering LD treatment also delayed the shoot senescence of one of the two potato varieties and decreased the number of tubers per plant in both varieties. The LD treatment delayed maturation of rice and mungbean, and decreased seed yield and 100-seed weight of peanut, although the shoot senescence of peanut was not apparently affected. Rapeseed, wheat, cotton and corn genotypes in this study did not show any sensitivity to post-flowering photoperiod. In triticale (an LD crop) exposure to short photoperiod post-flowering increased the number of spikes per plant perhaps due to a greater assimilate accumulation over a longer duration. The results from the current study as well as those from our previous experiments suggest that post-flowering photoperiod responses do exist in diverse field crops, and that there are strong genotypic differences in sensitivity and magnitude of response to post-flowering photoperiod. Photoperiod after flowering substantially regulates the source/sink relationship, and promotes partitioning and accumulation of assimilates to storage organs of crops when it favours the reproductive development of crops. 相似文献
9.
不同光温条件谷子光温互作模式研究及SiCCT基因表达分析 总被引:2,自引:0,他引:2
JIA Xiao-Ping YUAN Xi-Lei LI Jian-Feng WANG Yong-Fang ZHANG Xiao-Mei ZHANG Bo QUAN Jian-Zhang DONG Zhi-Ping 《作物学报》2020,46(7):1052-1062
光周期和温度是影响作物生长发育、生态适应性和产量的2个重要环境因素,揭示光温互作对作物生长发育的效应及其分子机制对育种实践和理论研究具有重要意义。本研究设置长日照高温、长日照低温、短日照高温、短日照低温4个光温处理,调查‘黄毛谷’抽穗期、株高、叶片数和穗长。结果表明,光周期对谷子的发育起关键作用,温度的改变不影响长日照比短日照延迟谷子生殖生长的效应,温度的作用随光周期的不同而异,短日照条件下,高温缩短谷子营养生长期而低温延长营养生长期,长日照条件下则相反;对谷子生殖生长的促迚作用是短日照高温短日照低温长日照低温长日照高温。利用RT-PCR技术从‘黄毛谷’叶片兊隆了一个CCT结构域基因(SiCCT),该基因编码286个氨基酸,属于CMF亚家族成员,基于CCT域基因氨基酸序列的系统迚化分析,谷子与高粱、玉米亲缘关系较近。实时荧光定量PCR分析发现, SiCCT基因在‘黄毛谷’叶片中高表达,其次为幼穗和叶鞘;长日照、短日照处理SiCCT基因均表现24h昼夜节律性特点,短日照七叶期表达水平最高,八叶期(抽穗)及穗后表达迅速降低,长日照七叶至十叶期‘黄毛谷’处于营养生长期,SiCCT基因维持较高表达水平;无论高温低温,长日照条件下SiCCT基因在各叶期表达量整体高于短日照处理,长日照条件下低温处理SiCCT基因的相对表达量明显低于高温处理, SiCCT基因的总体表达量与‘黄毛谷’营养生长期存在正相关。总之SiCCT基因受光周期调控,同时也受温度调控,因而推测SiCCT基因参与了光周期途径和感温性途径,并通过二者互作调控谷子营养生长和生殖生长的全过程。 相似文献
10.
Summary Photoperiod response of flowering in common bean (Phaseolus vulgaris L.) is thought to be controlled by the genes Ppd and Hr. However, cultivars also vary in the degree that cooler temperatures reduces their sensitivity to photoperiod. To examine the inheritance of this temperature sensitivity, crosses of cvs. Gordo x de Celaya and Flor de Mayo × Rojo 70 were evaluated at two sites differing in mean temperature and using 12.5-h natural photoperiod or 18-h artificially extended photoperiod. Under 18-h photoperiod at the warmer site, Palmira, no plants of the parents or of the F2 populations flowered, confirming that the parents were sensitive to photoperiod. Under 12.5-h photoperiod at the cooler site, Popayan, the parents for each cross flowered at similar dates and no segregation for days to flower was observed. However, under 18-h photoperiod, de Celaya and Rojo 70 and the F1 populations did not flower within 100 days after planting, while the F2 and F3 populations showed segregation that was consistent with single gene inheritance, late flowering being dominant. Late flowering at Popayan under 18-h photoperiod indicates a lack of temperature sensitivity, so temperature insensitivity of the photoperiod response was dominant to sensitivity. The name Tip, for temperature insensitivity of photoperiod response, is proposed for this gene, with the recessive form of this gene conditioning earlier flowering at cooler temperatures with long daylengths. It is recognized that the observed segregation patterns could represent the effect of multiple alleles at the Ppd or Hr loci, and studies are proposed to test this possibility with molecular markers and recombinant inbred lines. 相似文献
11.
为了加快育种进程,拓宽新品种的遗传基础,提高大豆在南繁条件下的杂交结实率,本研究选用7个东北春大豆早熟品种,在海南三亚进行光照处理和杂交技术试验,观察供试品种在长日照(18 h)处理和三亚自然短日照条件下植株形态、生长发育进程、花器官特征和花粉育性的变化,并研究光照处理、母本是否去雄和母本花蕾大小对杂交效果的影响。结果表明,海南冬季自然短日照致使大豆开花持续时间缩短,株高、花朵数量和单花重量降低,花朵及其各组成部分变小(P<0.01),花粉败育率上升(P<0.01)。以自然短日照处理植株作母本、长日照处理的材料作父本,在母本植株上选大花蕾,采用不去雄杂交,获得64.36%的杂交结实率,可基本满足杂交育种的需要。基于试验结果,提出了南繁条件下提高大豆杂交成功率的综合技术方案。 相似文献
12.
Photoperiod response genes play a major role in determining the climatic adaptability of European wheat varieties. Photoperiod
insensitivity, in the vast majority of photoperiod insensitive European wheat varieties, is probably determined by a Ppd1
allele originally derived from the old Japanese variety Akakomugi. Analysis of the pleiotropic effects of a Ppd1 allele from
the Italian variety Mara shows that, besides accelerating ear emergence time, Ppd1 also reduces plant height, tillering, and
spikelet numbers. Increases in spikelet fertilities more than compensate for reduced spikelet numbers, producing increased
numbers of grains per ear. In southern Europe, early flowering Ppd1 genotypes produce larger grain and greater yields. In
England and Germany, pleiotropic effects of Ppd1 on yield vary annually, depending on prevailing weather conditions, from
+9% to -16%, over a 10 year period in the United Kingdom. A possible alternative Ppd1 allele from the CIMMYT variety Ciano
67 was compared to that from Mara. Differences associated with complete substituted chromosomes were found to be due to linked
genes rather than different Ppd1 alleles. Examination of an alternative weaker gene for photoperiod insensitivity, Ppd2, shows
this to exert similar but less significant pleiotropic effects to Ppd1. In the UK, in each of three years of trialing, Ppd2
increased yield 6% more than Ppd1. Results of 10 years trialing show that in Central European countries, between areas where
photoperiod sensitive or photoperiod insensitive varieties have a clear adaptive significance, the annual variations in climate
make it extremely difficult for breeders to produce varieties with good adaptability to changing environmental conditions.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
13.
不同光周期条件下大豆生育期主基因的效应 总被引:4,自引:0,他引:4
以大豆生育期近等基因系为材料, 比较12 h短日照(SD)及16 h长日照(LD)条件下E1/e1、E2/e2、E3/e3、E4/e4、E5/e5、E7/e7等6对生育期相关主基因的效应。结果表明, 在大多数生育期基因型中, 显性位点延迟大豆的开花期和成熟期, 隐性位点提早开花期和成熟期。同一基因在不同遗传背景下的效应值不同, 显性位点可增强其他基因的效应, 说明各基因间存在互作。生育期基因的效应受光周期影响很大, 长日照可增强大豆生育期相关基因的效应, 短日照则相反。此外, 光周期对基因效应的影响因发育阶段不同而变化, 其中, E1基因在大豆营养生长阶段、E4基因在生殖生长阶段受光周期影响较大, 而E3基因在营养生长和生殖发育阶段均受光周期的严格调控。不同光照条件下生育期基因效应的分析结果, 可为不同生态区大豆品种生育期性状的定量设计提供依据。 相似文献
14.
环剥对苎麻开花的诱导效应 总被引:1,自引:1,他引:0
研究了5个品种(系)、3个环剥时期及两种密度下,环剥对苎麻(短日植物)开花的诱导效应。结果表明:环剥能诱导头麻成熟期已有花芽分化的品种(系)于5至6月的自然长日下只开雄花,比短日(10小时光照)处理株花蕾多、花期长,但环剥不能诱导同等条件下无花芽分化的品种开花。对成熟茎环剥比成熟前环剥、稀植比密植表现出更好的诱导效果。 相似文献
15.
Summary The release of extremely early maturing varieties has made it possible to cultivate rice in Hokkaido (NL45-42°) in Japan, the northern limit region of paddy rice cultivation. Until then, rice cultivation in this region has been impracticable due to the climate condition, especially short summer and long-day more than 15 hours during summer. Experiment results confirmed that the success of rice cultivation in this area depends on raising photoperiod insensitivity varieties with short basic vegetative growth period. Moreover, in this study, the genetic factors controlling the photoperiod insensitivity of Hokkaido varieties were analyzed by using 8 kinds of tester lines for three loci, E1, E2, and E3, controlling photoperiod sensitivity. It was found out that all the varieties examined carry el, a photoperiod insensitivity allele of E1 locus, but as for the other loci, E2 and E3, the existence of plural alleles were recognized. We have already clarified that almost all the japonica-type varieties grown in Japan (except Hokkaido) and Taiwan carry E1 bringing about strong photoperiod sensitivity. Accordingly, it can be concluded that el is the gene essential to Hokkaido varieties: the interchange of E1 with e1 enabled rice cultivation under long-day condition. 相似文献
16.
甜荞花型比率对其主要产量性状的影响 总被引:1,自引:0,他引:1
甜荞栽培种有长花柱(Pin,P型)和短花柱(Thrum,T型)两种花型,理论上两种花型比率约为1:1。田间调查发现:不同甜荞品种的花型比率略有不同,且花型比率的不同对甜荞的产量有较大影响。本研究以蒙0208、综甜2号、品甜荞1号3个甜荞品种为材料,以单株粒数和单株粒重两个产量性状为主要调查指标。通过构建T:P分别为1:9、2:8、3:7、4:6、5:5、6:4、7:3、8:2、9:1的甜荞花型比率,探讨甜荞花型比率与结实性之间的关系。研究结果表明:花型比率为4:6或6:4时,3个甜荞品种的两个产量性状表现最佳。当花型比率为1:1时,P型花植株的单株粒数和单株粒重优于T型花植株,某种花型的单株粒数和单株粒重一般是在其占比少的时候表现更好。通过本试验可以推断,当群体中T花型的比率高于80%时,甜荞的产量明显降低。 相似文献
17.
J. D. Berger S. P. Milroy N. C. Turner K. H. M. Siddique M. Imtiaz R. Malhotra 《Euphytica》2011,180(1):1-15
Arguably the most important adaptive criterion in annual crops is appropriate phenology that minimizes exposure to climatic
stresses and maximizes productivity in target environments. To date this has been achieved empirically by selecting among
diverse genotypes in target locations. This approach is likely to become inadequate with pending climate change because selection
is imposed on the outcome (flowering time) rather than the underlying mechanism (i.e. responses to daylength, ambient or vernalizing
temperatures). In contrast to the cereals, in legumes the interaction between phenological mechanisms and environmental selection
pressure is largely unknown. This paper addresses this shortcoming through photothermal modelling of chickpea germplasm from
the world’s key production areas using a meta-analysis of multi-environment trials located from 49° N to 35° S. Germplasm
origin had significant effects on temperature and daylength responsiveness, the former strongly correlated to vegetative phase
temperatures at the collection or development site (r = 0.8). Accordingly, temperature responses increase from winter- to spring-sown Mediterranean and Australian material, and
then to north, central & southern India. Germplasm origin also affects the relationship between photoperiod and temperature
response. In Eastern Mediterranean material a strong negative relationship (r = −0.77) enables temperature insensitive genotypes to compensate through a strong photoperiod response. Clearly, chickpea
evolution has selected for different phenological mechanisms across the habitat range. Given that under the anticipated global
warming temperature sensitive cultivars will flower relatively earlier than those responding largely to photoperiod, it is
important to exploit this diversity in developing better-adapted genotypes for future cropping environments. 相似文献
18.
Hot water treatment was applied to Tartary buckwheat (var. ‘Hokkai T8’) for emasculation. Apical clusters of flower buds were
soaked in a constant temperature water bath (42–44°C) in the afternoon and then the flowers which opened in the next morning
were used for the investigation of self-fertilization and the artificial pollination. Hand pollination was carried out by
rubbing the anthers taken from the male parent (var. ‘Hokkai T10’) to the stigma of the flowers treated by hot water. The
seed set by self-fertilization was almost 0% when treated at 42°C for 8 min or more, at 43°C for 5 min or more and at 44°C
for 3 min or more. With artificial pollination, the best performance was obtained when treated at 44°C for 3 min, in which
the seed set was 55.1% and the matured seed was obtained 37.7% of the hand-pollinated flowers. Nine out of 26 progeny seedlings
emerged and the cotyledonal color of them were all reddish green, probably indicating the hybrid of ‘Hokkai T8’ and ‘Hokkai
T10’. The hybridization was reconfirmed by the segregation in F2. The hot water treatment at 44°C for 3 min was available to other seven varieties. From 24.5% to 100% of the hand-pollinated
flowers set mature seeds though only one self-fertilized seed remained without artificial pollinations. This hot water treatment
must be practically useful in hybridization breeding of Tartary buckwheat. 相似文献
19.
Induction of fertile flowers in potato (Solanum tuberosum L.) by silver thiosulphate anionic complex
Summary The effect of gibberellic acid containing mixtures, silver thiosulphate and extended photoperiod on flowering induction in 16 non-flowering potato genotypes and on flowering enhancement in 14 normally potato flowering genotypes was studied in sub-tropical plains of India during short-day autumn crop season of 2000–2001 and 2001–2002. Extended photoperiod alone was not successful in induction of flowering. Silver thiosulphate in combination with extended photoperiod effectively induced flowering in 16 potato genotypes studied for flowering induction. Induced flowers of some genotypes were male fertile. Normal berry setting was observed on induced flowers and seeds obtained from such berries germinated normally. Gibberellic acid containing treatments were not very effective in flower induction as they induced some flowering only in few genotypes. In the normally flowering genotypes silver thiosulphate enhanced maximum flowering and duration of flowering to a great extent. 相似文献
20.
S. N. Nigam R. C. Nageswara Rao J. C. Wynne 《Journal of Agronomy and Crop Science》1998,181(2):117-124
Effects of temperature × photoperiod interaction on vegetative and reproductive growth were examined in three selected groundnut genotypes by growing them in controlled-environment growth chambers with three temperature regimes (22/18, 26/22, and 30/26°C, day/night) under long (12 h, long day), and short (9 h, short day) photoperiods. The effect of photoperiod on the total dry-matter production (TDM) was significant with the genotypes producing 32–72% greater dry matter under LD than SD. Temperature × genotype interaction effects were significant, with the dry-matter production being greatest at 26/22°C and least at 30/26°C and 22/18°C in two of the three genotypes. Leaf area (LA) was greater under LD than SD at all temperature regimes. LA accounted for 76% of the variation in shoot + root dry weight (R2= 0.76, P < 0.01). A lack of relationship between LA and pod weight or pod numbers suggested that the pod development is controlled by factors other than carbon assimilation. The temperature × photoperiod interaction was significant for root growth, with the root weight being maximal and photoperiod effects being minimal at 22/18°C, while at 26/22°C, root weight declined and photoperiod effects became prominent. Low temperature (22/18°C) affected the reproductive development by reducing the proportion of reproductive nodes in total (vegetative + reproductive) nodes. The conversion of pegs into pods, as indicated by pod to peg ratio (PPR), was lower in LD than in SD conditions. Results suggested that the PPR could be used as an indicator of genotypic sensitivity to photoperiod in groundnut. 相似文献