Coleoptile Senescence in Rice (Oryza sativa L.)

We investigated the cellular events associated with cell deathin the coleoptile of rice plants (Oryza sativa L.). Seeds germinatedunder submergence produced coleoptiles that were more elongatedthan those grown under aerobic conditions. Transfer of seedlingsto aerobic conditions was associated with coleoptile opening(i.e. splitting) due to death of specific cells in the sideof the organ. Another type of cell death occurred in the formationof lysigenous aerenchyma. Senescence of the coleoptile was alsonoted, during which discolouration of the chlorophyll and tissuebrowning were apparent. DNA fragmentation was observed by deoxynucleotidyltransferase-mediateddUTP nick end labelling (TUNEL) assay, and further confirmedby the appearance of oligonucleosomal DNA ladders in senescentcoleoptile cells. Two nucleases (Nuc-a and Nuc-b) were detectedby in-gel-assay from proteins isolated from coleoptiles. Nuc-a,commonly observed in three cell death phases required eitherCa²⁺or Mg²⁺, whereas Nuc-b which appeared during senescencerequired both Ca²⁺and Mg²⁺. Both nucleases were strongly inhibitedby Zn²⁺. Copyright 2000 Annals of Botany Company Aerenchyma, rice, cell death, coleoptile, fragmentation, nuclease, Oryza sativa, senescence, split, submergence, TUNEL     

The Remobilization of Nitrogen Related to Leaf Growth and Senescence in Rice Plants (Oryza sativa L.)

Rice plants (Oryzae sativa L.) grown in a nutrient solutionwere fed with (¹⁵NH₄)₂SO₄ during the 5 days of their young panicleformation. At the end of that time in the youngest leaf blade, which hadstarted to emerge during the labelling, absorbed-nitrogen accountedfor 37% of the increased nitrogen of the tissue; in the nextdeveloping leaf blade it accounted for 55%. Thus, remobilized-nitrogenoriginating from older patrs of the plant made up 63 and 45%,respectively, of their total nitrogen. The important contributionof the remobilized-nitrogen to the development of a leaf isevident. The remobilization of nitrogen in the 12th leaf blade on themain stem was examined in detail after labelling during itsdeveloping stage. The ¹⁵N level started to decrease soon afterthe end of the labelling period and continued to decrease untilfull senescence, although the total nitrogen in the same leafincreased until just after its complete expansion, suggestingthat even a young leaf plays a role as a supplier of remobilized-nitrogen. During the rapid decrease in the total nitrogen after its peakat full expansion of the leaf, the actual proportion of labelledabsorbed nitrogen remained nearly the same, indicating thatinflux of new nitrogen into a senescing leaf is very limited. (Received March 13, 1981; Accepted July 13, 1981)     

Relation between Leaf Age and Nitrogen Incorporation in the Leaf of the Rice Plant (Oryza sativa L.)

The relation between leaf age and the incorporation of nitrogeninto the leaf was examined in the 13th leaf blade of the riceplant, Oryza sativa L., after feeding it ¹⁵N-labelled ammoniumsulfate. The incorporation of nitrogen into the leaf was activeup to the maximum leaf nitrogen content; thereafter it decreasedquickly. At the beginning of senescence, when the nitrogen contentof the leaf had begun to decrease, the incorporation of ¹⁵Ndecreased to 28% of the value during development. At the middlestage of senescence, when the nitrogen content had decreasedto half the maximum, the incorporation was 13%. The incorporation of ¹⁵N into soluble proteins was examinedby gel filtration on Sephadex G-200. During development, largeamounts of ¹⁵N were incorporated into the ribulose bisphosphatecarboxylase-rich fraction. As the leaf aged, the incroporationof ¹⁵N into this fraction decreased more sharply than it didin other fractions. This tendency was more pronounced at thelate stage of senescence. We concluded that the amounts andkinds of protein synthesized in a leaf are closely related toleaf age. (Received November 24, 1981; Accepted June 17, 1982)     

NaCl-induced Senescence in Leaves of Rice (Oryza sativa L.) Cultivars Differing in Salinity Resistance

The influence of NaCl on senescence-related parameters (proteinand chlorophyll concentrations, membrane permeability and chlorophyllfluorescence) was investigated in young and old leaves of fiverice cultivars differing in salt resistance. NaCl hastened thenaturally-occurring senescence of rice leaves which normallyappears during leaf ontogeny: it decreased chlorophyll and proteinconcentrations and increased membrane permeability and malondialdehydesynthesis. Such an acceleration of deteriorative processes affectedall leaves in salt-sensitive cultivars while it was more markedin oldest than in youngest leaves of salt-resistant genotypes.NaCl-induced senescence also involved specific modifications,such as an increase in basal non-variable chlorophyll fluorescence(F ₀) recorded in all cultivars or a transient increase in solubleprotein concentration recorded in salt-resistant genotypes only.Alteration of membrane permeability appeared as one of the firstsymptoms of senescence in rice leaves and allowed discriminationamong cultivars after only 7 d of stress. In contrast, F _v/F _mratio (variable fluorescence/maximal fluorescence) was thesame for all cultivars during the first 18 d of stress and thuscould not be used for identifying salt-resistant rice exposedto normal light conditions. Relationships between parametersinvolved in leaf senescence are discussed in relation to salinityresistance of rice cultivars. Chlorophyll concentration; chlorophyll fluorescence; electrolyte leakage; magnesium; malondialdehyde; membrane permeability; NaCl; Oryza sativa L.; protein; rice; salinity resistance; senescence; UV absorbing substances     

水稻体细胞无性系变异

水稻体细胞无性系变异研究取得了很大进展 ,获得了大量抗病、抗逆、优质、矮杆等突变体。对这些突变体遗传分析表明 ,大多数突变性状由 1对或 2对基因控制。水稻体细胞无性系变异的发生与基因型、性状、继代时间、培养方式等有关 ,并具有内在的机制 ,点突变和反转录转座子插入可能是引起水稻无性系变异的两个重要原因。     

Why Nitrogen Use Efficiency Decreases Under High Nitrogen Supply in Rice (Oryza sativa L.) Seedlings

Hydroponic experiments were conducted in a greenhouse to examine the effects of different nitrogen (N) supply (low, 20 mg L⁻¹; intermediate, 40 mg L⁻¹; and high, 100 mg L⁻¹) on the growth, nitrogen use efficiency, and photosynthetic characteristics of rice seedlings (Oryza sativa L., cv. “Shanyou 63” hybrid indica. China). Leaf gas exchange was conducted to identify the photosynthetic-limiting factors in plants with high N supply. The results showed that (1) shoot biomass, leaf area, and tiller numbers per plant under low N were lower than under intermediate and high N supplies. No significant differences were observed between plants supplied with intermediate and high N. (2) About a 35% increase in leaf N content in plants fed by high N resulted in about a 15% increase in carboxylation efficiency (CE) and photosynthetic rate. (3) The noncorresponding increases in photosynthetic rate in rice seedlings fed by high N relative to low N resulted from Rubisco activity and/or CE. (4) The decreased Rubisco activity was induced by a relatively insufficient CO₂ supply under high N supply. These results indicated that insufficient CO₂ supply under high N supply accounted for the decreased Rubisco activity and the noncorresponding increases in photosynthetic rate to leaf N content, and as a result, decreased (photosynthetic) nitrogen use efficiency.     

Short- and Long-Term Effects of Salinity on Leaf Growth in Rice (Oryza sativa L.)

Addition of 50 mM NaCl to Oryza sativa L. had little effectupon the time of leaf initiation, but leaf mortality prior tothe normal phase of senescence was increased and the onset ofsenescence was advanced. There was no significant effect uponthe day-to-day pattern of growth, nor upon the ultimate length,of leaves that were developing at the time of, or shortly after,salinization with 50 mM NaCI. Leaves that developed after prolongedexposure of the plants to salinity were shorter. Addition ofNaCl, KC₁ or mannitol to the root medium brought about a cessationof leaf elongation within one minute. Growth at a reduced raterestarted abruptly after a lag period that depended upon theexternal concentration. Elongation rate recovered its originalvalue within 24 h after exposure to 50 mM NaCl, though not athigher concentrations. Addition of NaCl at concentrations upto 100 mM elicited no short-term effects upon photosyntheticgas exchange. Na uptake contributed to osmotic adjustment ofthe growing zone. When plants were rapidly exposed to 50 mMNaCl, no change in turgor pressure was detectable in the growingzone with the resolution of the miniature pressure probe used(about 70 kPa). It is concluded that the initial growth reductionin rice caused by salinization is due to a limitation of watersupply. A clear distinction is made between the initial effectsof low salinity which are recoverable and the long-term effectswhich result from the accumulation of salt within expanded leaves. Key words: Leaf elongation, gas exchange, photosynthesis, water relations     

Mechanism of Anther Dehiscence in Rice (Oryza sativa L.)

This paper presents a new explanation of the mechanism of antherdehiscence in rice during the period from floret opening topollen dispersal. The theca dehisced on the stomium in the apicalpart and the anther wall in the basal part of the large locule.Comparison of the anther dehiscence process under various airhumidity conditions showed that the process, until the splittingat the apical and basal parts, was a moisture-requiring processwhereas the widening of the splits in both parts was a desiccatoryprocess. Observation of the anther transverse section, revealedthe marked development of the U-shaped thick cell wall in theendothecium adjacent to these two splits. From these observations,the anther dehiscence mechanism may be explained as follows.At the time of anthesis, pollen grains swell rapidly in responseto the floret opening and cause the theca to bulge, rupturingthe septum. The pollen pressure combined with the inward bendingof the locule walls adjacent to the stomium causes splittingof the stomium in the apical part of the theca. At the sametime, the septum rupture extends to the bottom of the largelocule supported by the pollen pressure. After these processes,the locule walls adjacent to both splits straighten probablydue to their water loss. This straightening widens the splitsand the swollen pollen grains overflow from the widened splits.Copyright1999 Annals of Botany Company Anther dehiscence, Oryza sativa L., pollen grain swelling, rice, septum, stomium, theca.     

应用微卫星标记鉴别水稻籼粳亚种

应用70个微卫星标记分析了3个籼稻测验种和3个粳稻测验种的多态性,发现其中36个标记可以区分籼粳测验种。再以18个籼粳品种进一步筛选,找到了分布于12条染色体的21个籼粳特异性微卫星标记。在这21个标记中,20个在籼粳亚种间带型相异,其中7个在亚种内带型一致,13个在亚种内带型不一致;1个标记在12个籼稻品种和1个粳稻品种检测到相同的带型,其余11个粳稻品种具有另一种带型。微卫星标记和RFLP标记检测籼粳亚种不仅具有一致性,而且还有互补性。 Abstract:Six indica and japonica testers were assayed using 70 microsatellite markers.Thirty-six markers distinguishing indicas from japonicas were detected.By further-screening among 18 indica and japonica varieties,21 markers distributed on 12 rice chromosomes were found to be indica-japonica differentiated.No indica varieties shared same patterns with any japonica varieties at 20 marker loci,of which identical patterns were observed within subspecies at 7 loci while within-subspecies variations were observed at 13 loci.At the remaining locus,12 indica and 1 japonica varieties had the same allele,while other 11 japonica varieties had another allele.It also showed that SSLP was not only consistent,but also complementary,to RFLP for the subspecies identification.     

水稻米粒延伸性的遗传剖析

以籼稻ZYQ8与粳稻JX17为亲本的DH群体作为研究材料,考察DH群体及双亲的米粒延伸率相关性状,并使用该群体的分子连锁图谱进行QTL分析.共检测到14个与稻米延伸性有关的QTL,包括2个粒长QTL、7个饭粒长QTL和5个米粒延伸率QTL,分别位于第1、2、3、5、6、7、10、11和12染色体.所有QTL的LOD值介于2.26～9.25,分别解释性状变异的5.31%～17.21%.在第3染色体上的G249～G164、第6染色体上的G30～RZ516和第10染色体上的G1082～GA223区间同时检测到控制饭粒长和米粒延伸率的QTL.米粒延伸性受多基因控制,Wx基因与位于第6染色体上的qCRE-6的G30～RZ516区间相近,对米饭的延伸性具重要影响.     

栽培稻旱胁迫叶片相关性状的遗传解析

利用籼稻窄叶青8号(ZYQ8)和粳稻京系17(JX17)衍生的加倍单倍体(DH)群体127个株系,2002年在杭州采用田间断水法栽培,在水分胁迫下,对叶片的卷叶、相对含水量和电导率3个性状进行了评价和QTL分析。结果表明,3个性状在DH群体中均存在双向超亲分离,接近正态分布,受数量性状基因的控制;检测到影响这些性状的6个QTL,其中卷叶3个(qLR—1,qLR—5和qLR—11)、相对含水量2个(qRWC—1和qRWC—6和电导率1个(qERC—6）。旱胁迫时,目测卷叶方便易行,适于对大批品种或资源筛选,对抗旱栽培稻品种的筛选和利用具有一定的指导意义。     

Ethylene-Induced Polyamine Accumulation in Rice (Oryza sativa L.) Coleoptiles

The light-harvesting complex (LHC) of photosystem II is composed of several different pigment-binding apoproteins. We have identified a cDNA clone LHCIIa-1 encoding the 31-kilodalton LHC IIa (CP29, Chl a/b-P1) apoprotein of barley (Hordeum vulgare). Direct protein microsequencing of an internal peptide fragment from the LHC IIa apoprotein has been used to identify unequivocally the cDNA clone as that coding for the LHC IIa apoprotein. Microsequencing of the 28-kilodalton LHC IIc protein (CP26) showed only minor sequence similarity to the LHC IIa protein, indicating that they are two different gene products. LHCIIa-1 codes for a protein of 286 amino acid residues (molecular weight, 31,308), which displays strong similarities to other pigment-binding LHC proteins, and yet contains an additional 42 amino acid residue segment. Two regions of strong intramolecular sequence similarity are also observed.     

Nitrogen Use Efficiency of Rice Cultivars (Oryza sativa L.) Under Salt Stress and Low Nitrogen Conditions

Improving nitrogen use efficiency (NUE) under salt stress has become crucial for rice as it is increasingly facing two major environmental constraints: excessive nitrogen fertilization and soil salinization. However, the interaction between salinity and N levels is very complex and has not yet been considered from the perspective of reduced nitrogen input. We conducted a hydroponic experiment at the early tillering stage on the Yoshida solution to evaluate the impact of rising NaCl and decreasing N application on NUE of four rice cultivars cultivated under three NaCl (0, 56, and 113 mM) and four N (2.86, 1.43, 0.72, and 0.36 mM) concentrations. After 4 weeks, physiological NUE (pNUE), absorption NUE (aNUE), agronomical NUE (agNUE), N transport efficiency (NTE), and physiological traits were evaluated. Significant interactions between N and NaCl-applied concentrations were found in all measured parameters. In all cultivars, increasing the NaCl-applied concentration markedly decreased aNUE and agNUE. For each NaCl treatment, lowering the N applied sharply increased aNUE and agNUE, and this effect was stronger when the NaCl applied was higher. The effect of N lowering on pNUE depended on the NaCl treatment: it enhanced pNUE in the absence of NaCl but had no influence under the highest NaCl-applied concentration. Cultivars largely differed in response to NaCl. The aNUE—but not pNUE—differed between salt-tolerant and salt-sensitive cultivars: aNUE markedly decreased with NaCl concentration in the most salt-sensitive cultivar, whereas it was the highest at the intermediate NaCl concentration in the most salt-tolerant cultivar, especially under low N levels. This finding suggests that under salt conditions, the use of salt-tolerant rice genotypes combined with reducing N level application is necessary to improve NUE. The study of NUE in rice should be focused on the improvement of aNUE with a strong emphasis on the salt tolerance of cultivars.

     

Influence of Osmotic Adjustment on Leaf Rolling and Tissue Death in Rice (Oryza sativa L.)

Osmotic adjustment, measured by the lowering of the osmotic potential at full turgor, and its influence on leaf rolling and leaf death was assessed in the lowland rice (Oryza sativa L.) cultivar IR36 in both the greenhouse and field. The degree of osmotic adjustment varied with the degree and duration of stress, but was usually 0.5 to 0.6 megapascal (maximally 0.8 to 0.9 megapascal) under severe stress conditions. In leaves in which osmotic adjustment was 0.5 to 0.6 megapascal, leaf rolling and leaf death occurred at lower leaf water potentials in adjusted than in nonadjusted leaves. We conclude that osmotic adjustment aids in the drought resistance of rice by delaying leaf rolling, thereby maintaining gas exchange, and by delaying leaf death.     

水稻对叶瘟和穗瘟部分抗性的遗传分析

在一个水稻籼籼交重组自交系群体中,选用由感病株系构成的2个亚群体和2个不同的稻瘟病菌小种,进行了水稻对叶瘟部分抗性的QTL定位,还选用由感病而且抽穗期相近的株系构成的亚群体和另一个病菌小种,进行了水稻对穗瘟部分抗性的QTL定位,将病叶面积百分比(DLA)、病斑大小(LS)和病斑数(LN)作为对叶瘟部分抗性的性状,将病斑长度(LL)和孢子量(CA)作为对穗瘟部分抗性的性状。所构建的图谱包含168个标记。应用QTLMapper 1．01b,共检测到11个表现主效应的QTL和28对双因子互作,有3个表现主效应的QTL参与对同一性状的互作。QTL的主效应对单一性状的贡献率为4．7％～38．8％,而上位性效应对单一性状的贡献率为16．0％～51．7％,QTL的主效应对大多数性状的贡献率小于互作效应,表明互作效应对于部分抗性的重要作用。对穗瘟部分抗性的两个性状LL和CA,所检测到QTL总效应的贡献率分别达到70．6％和82．6％,表明由排除了主效抗病基因的感病株系组成的亚群体适合于进行部分抗性QTL定位。     

超高产杂交稻剑叶衰老过程中PSII功能的变化

对田间自然条件下培矮64S/E32和对照汕优63的剑叶衰老过程中PSII光化学效率、光能耗散和叶黄素循环组分的动态变化进行了研究.结果表明,水稻剑叶衰老过程中PSⅡ光化学效率(F/Fm)、PSII量子产量(φPSII)、光化学猝灭系数(qP)和光合速率(Pn)均降低,但非辐射热耗散(NPQ)、叶黄素循环库和中午时的脱环氧化状态则升高.移栽后55-75 d两品种剑叶的φPSII和qP变化相近,此后培矮64S/E32比汕优63下降缓慢.在生育后期的衰老过程中培矮64S/E32剑叶的PSII功能比汕优63下降慢,并具有更高的光能利用效率.     

水稻分蘖角度的ＱＴＬs分析

分蘖角是水稻株型构成的重要性状之一,在育种上人有极其重要的意义,利用分蘖角度差异显著的１对籼粳亲本,将其杂交Ｆ１代花培加倍,构建了１个ＤＨ群体,考察了１１５个ＤＨ株系的分蘖角度,并使用该群体构建的分子图谱进行数量性状座痊（ＱＴＬs)分析。分别在第９和１２个染色体上检测３个ＱＴＬs(qTA-9a、qTA－９b和qTA－１２）,贡献率分别为２２．７％、１１．９％和２０．９％,其加性效应均为负,表明由分蘖角度较大的窄占青８号的基因控制,并讨论了这种由主产和微效基因控制的分蘖性状在育种学上的应用。     

Chronopathological Aspects of Disease Incidence in Rice (Oryza sativa L.)

Rice seedlings maintained under uncontrolled glasshouse conditions were inoculated with conidial suspensions of a fungal pathogen, Helminthosporium oryzae, at various times during the 24 h. Significant increase in the percent germination and germ tube length of conidia were observed in the rice samples inoculated at 02:00 and 06:00h. The 24 h temporal variation in leaf temperature was positively correlated with variation in stomatal movements. The results indicate a 24 h rhythm in the behavior of the fungal pathogen on the host in relation to the conditions of the growing environment. In all the inoculated seedlings, the appearance of a large number of brown leaf spots was confined to the light span. Among the plants inoculated, earlier initiation of brown leaf spot appearance, maximum number of leaf spots, and highest disease severity were observed when plants were inoculated at 02:00h. There was a positive correlation between disease severity of the host and in vivo values of percent germination of conidia and germ tube length of the pathogen in plants inoculated between 02:00 and 06:00h. The findings of this study implicate that light intensity and temperature could play a predominant role in controlling disease susceptibility rhythms in plants.     

QTL Analysis of Aluminum Resistance in Rice (Oryza sativa L.)

Aluminum (Al) toxicity is considered as one of the primary causes of low-rice productivity in acid soils. In the present study, quantitative trait loci (QTLs) controlling Al resistance based on relative root elongation (RRE) were dissected using a complete linkage map and a recombinant inbred lines (RILs) derived from a cross of Al-tolerant japonica cultivar Asominori (Oryza sativa L.) and Al-sensitive indica cultivar IR24 (O. sativa L.). A total of three QTLs (qRRE-1, qRRE-9, and qRRE-11) were detected on chromosomes 1, 9, and 11 with LOD score ranging from 2.64 to 3.60 and the phenotypic variance explained from 13.5 to 17.7%. The Asominori alleles were all associated with Al resistance at all the three QTLs. The existence of these QTLs was confirmed using Asominori chromosome segment substitution lines (CSSLs) in IR24 genetic background (IAS). By QTL comparative analysis, the two QTLs (qRRE-1and qRRE-9) on chromosomes 1 and 9 appeared to be consistent among different rice populations while qRRE-11 was newly detected and syntenic with a major Al resistance gene on chromosome 10 of maize. This region may provide an important case for isolating genes responsible for different mechanisms of Al resistance among different cereals. These results also provide the possibilities of enhancing Al resistance in rice breeding program by marker-assisted selection (MAS) and pyramiding QTLs.