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Cytoplasm affects grain weight and filled-grain ratio in indica rice

BMC Genetics volume 12, Article number: 53 (2011) Cite this article

Abstract

Background

Cytoplasmic effects on agronomic traits -involving cytoplasmic and nuclear genomes of either different species or different cultivars - are well documented in wheat but have seldom been demonstrated in rice (Oryza sativa L.). To detect cytoplasmic effects, we introgressed the nuclear genomes of three indica cultivars - Guichao 2, Jiangchengkugu, and Dianrui 449 - into the cytoplasms of six indica cultivars - Dijiaowujian, Shenglixian, Zhuzhan, Nantehao, Aizizhan, and Peta. These 18 nuclear substitution lines were evaluated during the winter season of 2005 in Sanya, Hainan, China, and during the summer season of 2006 in Kunming, Yunnan, China. The effects of 6 cytoplasm sources, 3 nucleus sources, 2 locations and their interactions were estimated for plant height, panicle length, panicle number per plant, spikelet number per panicle, grain weight, filled-grain ratio, and yield per plot.

Results

For five of the seven traits, analysis of variance showed that there were no significant cytoplasmic effects or interactions involving cytoplasmic effects. The effect of cytoplasm on 1000-grain weight was highly significant. Mean 1000-grain weight over the two locations in four of the six cytoplasms clustered close to the overall mean, whereas plants with Nantehao cytoplasm had a high, and those with Peta cytoplasm a low mean grain weight. There was a highly significant three-way interaction affecting filled-grain ratio. At Sanya, cytoplasms varied in very narrow ranges within nuclear backgrounds. Strong cytoplasmic effects were observed only at Kunming and in only two of the three nuclear backgrounds; in the Jianchenkugu nuclear background, there was no evidence of strong cytoplasmic effects at either location. In the Dianrui 449 and Guichao 2 nuclear background evaluated at Kunming, filled-grain ratios of the six cytoplasms showed striking rank shifts

Conclusions

We detected cytoplasmic variation for two agronomically important traits in indica rice. The cytoplasm source had a significant effect on grain weight across the two experimental locations. There was also a significant cytoplasmic effect on filled-grain ratio, but only in two of three nuclear background and at one of the two locations. The results extend our previous findings with japonica rice, suggesting that the selection of appropriate cytoplasmic germplasm is broadly important in rice breeding, and that cytoplasmic effects on some traits, such as filled-grain ratio, cannot be generalized; effects should be evaluated in the nuclear backgrounds of interest and at multiple locations.

Background

Reductions in genetic diversity are of major concern to breeders, geneticists, and the agricultural community in general. In many crops, genetic improvement is usually associated with reduced genetic diversity in the gene pools used to develop the new cultivars, despite the fact that genetic uniformity is believed to increase the potential vulnerability of the crop to biotic and abiotic stresses [1].

The genetic base of cultivars of rice is narrow because of the long history of domestication and genetic improvement. Pedigree analysis indicates that the genetic diversity of indica irrigated rice in China depends on a genetic core derived from the varieties Aizizhan, Nantehao, Shenglixian, Peta, and Dijiaowujian [2]. Between three and six sources of genetic material per location have used by breeders of japonica rice cultivars in China [2, 3], Japan [4], Brazil [1], Senegal [5], and the United States [6], with the cultivars Reimei and Xinan 175 being used as source material at more than one location.

The cytoplasmic genetic base of improved cultivars of rice is also narrow. The WA (wild abortion) cytoplasm makes rice plants male sterile, facilitating the production of cultivars of hybrid rice [7], which explains why 90% of Chinese cultivars of hybrid rice have WA cytoplasm [2]. The situation is similar for cultivars of indica rice: most IR varieties--developed by the International Rice Research Institute (IRRI)--trace to the same maternal parent, Cina, implying that components of their cytoplasm are the same [8]. Cina, which has same cytoplasm as the cultivar Peta, is the ultimate maternal parent of 75% of the new (post-IR8) varieties in Sri Lanka, 74% of those in Indonesia, 62% of those in Bangladesh, 60% of those in Korea, 50% of those in the Philippines and 25% of those in Thailand [9]. Eight out of 11 common irrigated varieties in Latin America in the late 1980 s had Cina as a maternal source [10]. Cytoplasms of Aizizhan, Nantehao, Shenglixian, and Cina accounted for 66% of the cytoplasm for 529 indica cultivars developed between 1950 and 1984 in southern China [11]. Among 40 diversified cytoplasm resources, cultivar 63-83 was the cytoplasm donor to 60% of upland rice varieties released by the Research Institute for Tropical Agriculture and Food Crops (IRAT) in China [5]. Four of the five main sources of nuclear genetic material in U.S. rice cultivars -- Rexoro, Caloro, Colusa, and Blue Rose -- were also used as core cytoplasm sources in the U.S. [12].

In wheat, another crop with a narrow germplasm base narrowed by centuries of breeding, cytoplasmic effects have been demonstrated using both alloplasmic sources (from related species) [13, 14] and euplasmic cytoplasm (from other wheat cultivars) [15–17]. Using reciprocal crossing, maternal effects have been reported for several traits in rice, including low temperature tolerance [18], grain weight [19, 20], protein content [21, 22], chalkiness [23], milling quality traits [24], panicle number [25], plant regeneration rates [26], hybrid vigor [27, 28], and crossability [29].

Research on direct effects of rice cytoplasm has mostly been a quest for cytoplasmic male sterility (CMS) and fertility restoration genes [8]. Compared to the amount of research reported on nuclear effects, the cytoplasmic effect on important agronomic traits in rice has been only sparsely studied. The few reports on maternal effects mentioned above used a reciprocal crossing method. However, this method is not the optimal way to dissect independent cytoplasmic effects because the F1 progeny of reciprocal crosses inherit nuclear genetic information from both parents. Therefore, in order to isolate a purely cytoplasmic effect, additional crosses using the same maternal lineage must be made [30]. After 10 backcrosses to the male parent of an F1 hybrid, the proportion of progeny that are heterozygous at any individual locus is 1 in 1024. In plants developed this way, 99.9% of the nuclear alleles are expected to be derived from the male parent used in the original cross, while the cytoplamic DNA and approximately 0.1% of the nuclear alleles are derived from the female parent used in the original cross. Using recurrent backcrosses to create nuclear substitution lines, we previously reported a purely cytoplasmic effect on yield, width of flag leaf, and low temperature tolerance in japonica rice [31]. To estimate true cytoplasmic effects for indica rice, 18 BC10F2:3 lines were constructed by using 6 core parents of indica rice as female parents crossed with 3 recurrent male parents. Herein we report the finding that cytoplasm and its interaction with the nuclear genome and environment can affect grain weight and filled-grain ratio in indica rice.

Results and Discussion

Cytoplasmic effects

Analysis of data from 18 lines representing all combinations of 6 cytoplasms and 3 nuclei and grown at two locations showed highly significant (P ≤ 0.001) nuclear effects for all seven traits investigated (analyses of variance not shown). The location effect was also highly significant for panicle number per plant, spikelet number per panicle, filled-grain ratio, panicle length, and plant height, but not for 1,000-grain weight (grain weight) and yield. These results indicate that the nuclear genome was a major factor in expression of important agronomic traits, while most traits were also affected by location.

Among the six core indica cytoplasms, there were significant (P ≤ 0.01) genetic differences in 1,000-grain weight (Table 1). Peta cytoplasm averaged across three nuclear backgrounds was associated with a 1.6 g lower 1,000-grain weight than Nantehao cytoplasm averaged across the same three nuclear backgrounds (Table 2). Cytoplasms of Dijiaowujian, Zhuzhan, Shenglixian, and Aizizhan averaged across these three nuclear backgrounds exhibited 1,000-grain weights that were intermediate between and significantly different from Peta (P ≤ 0.05) and Nantehao (P ≤ 0.01) (Table 2).

Table 1 Analysis of variance for 1,000-grain weight and filled-grain ratio
Full size table
Table 2 Mean 1,000-grain weights for six cytoplasms averaged across three nuclear backgrounds of indica rice
Full size table

The highly significant effect of cytoplasm on grain weight was consistent with the results of Chandraratna in 1960 [14] and Somrith in 1979 [15], who used the reciprocal crossing method to show that the cytoplasm affects grain weight. Both the nuclear substitution method (ours) and the reciprocal crossing method (Chandraratna's and Somrith's) showed that cytoplasm or cytoplasm-nucleus interactions affected grain weight, which is a major component of yield and grain quality in rice production.

In our experiment, the location effect alone was non-significant for 1,000-grain weight, but there was a highly significant (P ≤ 0.001) effect due to interaction between location and nuclear effects (Table 1). These results--showing that the change of grain weight in rice was mainly dependent on the effect of both cytoplasm and nucleus, while the location exerted an effect via interaction with the nucleus--were consistent with the conclusions of Pham [32]. This strongly suggests that in future rice breeding, genetic studies, and germplasm resources research, the role of cytoplasm should receive more attention.

There was a highly significant three-way interaction affecting filled-grain ratio (Table 1). Cytoplasm-nucleus interactions were significant at both locations, but the main effect of cytoplasm was significant only at Kunming (Table 3). That led us to dissect further the effect of cytoplasm and its interaction with the nucleus and location.

Table 3 Analyses of variance for filled-grain ratio at two locations
Full size table

Effects of cytoplasm and interaction with nucleus and location

Despite the significance of cytoplasmic-nuclear interaction for filled-grain ratio at Sanya, cytoplasms varied in very narrow ranges in each of the three nuclear backgrounds (in Figure 1, the grey, left-hand bar in each pair). Strong cytoplasmic effects were observed only at Kunming, but in only two of the three nuclear backgrounds: Dianrui 449 and Guichao 2 (in Figure 1, the black, right-hand bar in each pair); in the Jianchenkugu nuclear background, there was no evidence of strong cytoplasmic effects at either location.

Figure 1
figure 1

Mean filled-grain ratios for six cytoplasms in three nuclear backgrounds at two locations. The left, grey bar in each pair represents the mean in Sanya: the right, black bar represents Kunming. Within each location-nuclear background combination, mean bars labeled with different letters are significantly different at the P = 0.05 level.

Full size image

At Kunming, filled-grain ratios associated with the six cytoplasms showed striking rank shifts in Dianrui 449 and Guichao 2 nuclear backgrounds (Figure 1, top and bottom). The mean for lines with Peta cytoplasm, for example, was in the lowest group of lines with the Guichao 2 nuclear genome, but Peta cytoplasm exhibited the highest filled-grain ratio. Lines with Shenglixian cytoplasm showed the opposite pattern to that of Peta, being in the top group in the Guichao 2 nuclear background while ranking lowest in the Dianrui 449 background.

The cytoplasmic-nuclear interaction based both locations for the rest traits, which were plant height (cm), panicle length(cm), panicle number per plant, spikelet number per panicle, 1,000-grain weight (g) and yield per plot (kg), shown in Additional Files 1, 2, 3, 4, 5, 6 and 7.

Implications for rice breeding

Cytoplasmic variation represents a largely unexplored genetic resource for indica rice breeding programs, and exploitation of all available genetic resources is seen as necessary for avoiding a future cereal "yield plateau" [33]. Increased grain weight is one way to increase sink strength, which itself is a means of increasing cereal yield potential [34]. Although the nuclear effect for grain weight was larger than the cytoplasmic effect in this study (Table 1), nuclear genetic variation for grain weight is small compared with that for other agronomic traits [35]. The six core cytoplasms of indica rice were evaluated in this study. Evaluation of germplasm collections may reveal that other cytoplasmic sources not studied herein are superior for increasing indica rice grain weight.

Rice breeders are already interested in diversifying the cytoplasmic base of cultivar development programs to reduce the chance of disease epidemics. The vulnerability of cytoplasmic uniformity was illustrated in the classic case of Southern corn leaf blight caused by Helminthosporium maydis. An epidemic of the blight in 1970 devastated the U.S. maize crop because a disease-susceptible cytoplasm had been widely used in the development of male-sterile. Rice is similarly vulnerable, as demonstrated by the fact that WA cytoplasm affects the expression of bacterial blight reaction significantly [36] and is more seriously infected by blast isolate 90-2 than are its maintainers [37]. The discovery that cytoplasmic diversity affects other agronomic traits (both positively and negatively) makes it essential that cytoplasms being evaluated for disease resistance and CMS also be carefully evaluated for effects on other traits such as grain weight and filled-grain ratio.

The significant interaction effects we found between cytoplasm and nucleus and/or location have important implications for breeding programs. If elite nuclei are substituted into different cytoplasms to utilize cytoplasmic genes for CMS, disease resistance or agronomic traits, the resulting alloplasmic lines must be thoroughly tested in all nuclear-cytoplasmic combinations at all target locations even if the original elite lines were locally adapted. On the other hand, perhaps cytoplasmic substitution could be a useful method for generating location-specific cultivars from elite lines without disrupting favorable combinations of nuclear genes, including transgenes.

Conclusions

Compared with nuclear genes, cytoplasmic genes played a modest but statistically significant role in determining grain weight and filled-grain ratio of indica rice lines. The cytoplasmic effect for grain weight was significant across locations but the effect on filled-grain ratio was significant only as an interaction with location or as an interaction with nuclei at one location. These results suggest that useful genetic variation for agronomic traits may be present in the indica cytoplasmic gene pool. The unpredictable--but not surprising--interaction of cytoplasm source with nucleus source and location for one trait in this study suggests that breeders should beware of assuming that a particular cytoplasm will be equally adaptive in all locations or that nuclei and cytoplasms can be substituted freely without extensive testing in each location. On the other hand, nuclei with elite combinations of genes for yield, grain quality or other traits could be substituted into a number of distinct cytoplasms in the hopes of finding combinations better adapted for particular locations than the original nucleus donor cultivar.

Methods

Materials

Six major cultivars of indica rice -- Dijiaowujian, Shenglixian, Zhuzhan, Nantehao, Aizizhan, and Peta -- were used as female parents in crosses with 3 other indica rice cultivars: Guichao 2, Jiangchengkugu, and Dianrui 449. The latter 3 cultivars were used as recurrent parents in 10 backcrosses to form BC10F1 nuclear substitution lines, which were then selfed to produce the BC10F2 generation. Plants from this generation were selfed and the seeds were bulked for planting four replicates at two locations.

Experiment

Eighteen nuclear substitution lines of BC10F2:3 and their parents were sown on 5 November, and transplanted on 26 November, 2005, in Sanya, Hainan (November-April) for agronomic evaluation in the winter cropping season at a tropical location. Parental cytoplasm-nucleus combinations were excluded, in order to maintain a factorial design of six cytoplasmic genomes by three nuclear genomes. The traits measured were yield per plot (kg), 1,000-grain weight (g), panicle number per plant, spikelet number per panicle, filled-grain ratio (%), panicle length (cm), and plant height (cm). Plot size was 1.5 m × 2.5 m. Plant spacing was 15 cm between plants within a row and 25 cm between rows. The design was a randomized complete block with four replicates. The experiment was repeated at the Yunnan Academy of Agricultural Sciences, Kunming, from March to September 2006 for agronomic evaludation at a subtropical location. Cultural and management practices, including fertilizer applied (15 kg ha-1 of N, P, and K), were similar for both experiments at Sanya and Kunming.

Statistical analysis

Analysis of variance of the 6 × 3 factorial genetic design was used in order to determine in a single comprehensive analysis which among the seven traits were influenced by differences in the cytoplasmic genome and whether those effects depended on the nuclear background, the environment, or both. That preliminary information allowed us then to examine in more detail the differences and rankings of individual cytoplasms where significant differences occurred. Except for yield per plot, all data were from observations on 10 individuals selected randomly from each plot, and the plot mean was used in the analysis of variance. Fixed model analyses using type III sums of squares in SAS PROC GLM [38] were used to detect effects of nucleus, cytoplasm, and interaction between cytoplasm, nucleus, and location. For filled-grain ratio, arscin transformation of the ratio was performed before the analysis. If the three-way interactional effect among cytoplasm, nucleus, and location was significant for traits investigated, the least-squares means (LS-means) of fixed effects was employed to analyze the cytoplasmic effects within each location and nucleus. Duncan's multiple range test was used for multiple comparisons of the effect of cytoplasm and cytoplasm interaction with nucleus and location.

References

  1. Chatel M, Guimaraes E, Ospina Y, Borrero J: Improvement of upland rice using gene pools and populations with recessive male-sterility gene. Upland rice research in partnership. Edited by: Piggin C, Courtois B, Schmi V. 1996, International Rice Research Institute, P.O. Box 933, Manila, Philippines, 284-298.

    Google Scholar 

  2. Lin SC, Min SK: Rice varieties and their genealogy in China. 1991, Shanghai Science and Technology Press, Shanghai, China

    Google Scholar 

  3. Yang SX: Rice in Yunnan. Rice in China. Edited by: Xiong ZM, Cai HF, Min SK, Li BC. 1992, China Agricultural Science and Technology Press, Beijing, 421-436.

    Google Scholar 

  4. Kikuchi F: Semidwarfing genes of high yielding rice varieties in Japan. Rice Genetics. 1986, International Rice Research Institute, P. O. Box 933, Manila, Philippines, 85-295.

    Google Scholar 

  5. Hu FY, Tao DY, Yang GF, Yang JY: Genealogical analysis of IRAT upland rice varieties. Rice cultivation in highland areas, Proceedings of the CIRAD conference held at Antananarivo, Madagascar. Edited by: Poisson C, Rakotoarisoa J. 1997, CIRAD, Montpellier, France, 181-184.

    Google Scholar 

  6. Dilday RH: Contributions of ancestral lines in the development of new cultivars of rice. Crop Science. 1990, 30: 905-911. 10.2135/cropsci1990.0011183X003000040030x.

    Article  Google Scholar 

  7. Yuan LP: The concept of the strategy of hybrid rice breeding. Hybrid Rice. 1988, 2: 1-3.

    Google Scholar 

  8. Khush GS, Virk PS: IR Varieties and Their Impact. 2005, Los Banos (Philippines): International Rice Research Institute, 163-

    Google Scholar 

  9. Hargrove TR, Coffman WR, Cabanilla VL: Genetic interrelationships of improved rice varieties in Asia. IRRI Research Paper Series 23. 1979, International Rice Research Institute. P.O. Box 933, Manila, Philippines, 34-

    Google Scholar 

  10. CIAT (Centro Internacional de Agricultura Tropical): Rice program 1986-1989 Report, Working document No. 92. 1991, CIAT, Cali, Colombia, 109-113.

    Google Scholar 

  11. Gu MH, Pan XB, Li X: Genetic analysis of the pedigrees of the improved cultivars in Oryza sativa LSubsp. Hsien in South China. Scientia Agricultura Sinica. 1986, 1: 41-48.

    Google Scholar 

  12. Mackill D, McKenzie : Origin and characteristics of U.S. rice cultivars. Rice Origin, History, Technology, and Production. Edited by: Smith CW, Dilday RH. 2003, Hoboken, John Wiley & Sons, 87-100.

    Google Scholar 

  13. Ekiz H, Konsak CF: Nuclear and cytoplasmic control of anther culture response in wheat. I. Analyses of alloplasmic lines. Crop Science. 1991, 31: 1421-1427. 10.2135/cropsci1991.0011183X003100060005x.

    Article  Google Scholar 

  14. Ekiz H, Safi Kiral A, Akcin A, Simsek L: Cytoplasmic effects on quality traits of bread wheat (Triticum aestivum L.). Euphytica. 1998, 100: 189-196. 10.1023/A:1018382106978.

    Article  Google Scholar 

  15. Ekiz H, Konsak CF: Nuclear and cytoplasmic control of anther culture response in wheat. III. Common wheat crosses. Crop Science. 1991, 31: 1432-1436. 10.2135/cropsci1991.0011183X003100060007x.

    Article  Google Scholar 

  16. Voluevich EA, Palilova AN: Effect of maternal cytoplasm on resistance to brown rust in bread wheat. Tsitologiya I Genetika. 1988, 22: 34-37.

    Google Scholar 

  17. Ozgen M, Turet M, Avci M: Cytoplasmic effects on the tissue culture response of callus from winter wheat mature embryos. Plant Cell Tissue and Organ Culture. 2001, 64: 81-84. 10.1023/A:1010609603915.

    Article  Google Scholar 

  18. Ratho SN, Pradhan SB: Cytoplasmically controlled cold tolerance in a cytoplasmic-genetic male sterile line of rice. Euphytica. 1992, 58: 241-244.

    Article  Google Scholar 

  19. Chandraratna MF, Sakai KI: A biometrical analysis of matroclinous inheritance of grain weight in rice. Heredity. 1960, 14: 365-373. 10.1038/hdy.1960.35.

    Article  Google Scholar 

  20. Somrith B, Chang TT, Jackson BR: Genetic analysis of traits related to grain characteristics and quality in two crosses of rice. IRRI Research Paper Series 35. Edited by: International Rice Research Institute, Los Banos, Philippines. 1979

    Google Scholar 

  21. Chang TT, Lin FH: Diallel analysis of protein content in rice. Agronomy Abstracts. 1974, 65-

    Google Scholar 

  22. Shi CH, Xue JM, Yu YG, Yang XE, Zhu J: Analysis of genetic effects on nutrient quality traits in indica rice. Theor Appl Genet. 1996, 92: 1099-1102. 10.1007/BF00224055.

    Article  CAS  PubMed  Google Scholar 

  23. Xu YB, Shen ZT: Maternal effect on chalkiness in rice kernels. RGN. 1988, 5: 111-113.

    Google Scholar 

  24. Shi CH, J Zhu J: Analysis of seed, cytoplasmic, and maternal genetic effects on rice quality traits. IRRN. 1995, 20 (2): 4-

    Google Scholar 

  25. Wu HP: Studies on the quantitative inheritance of Oryza sativa L. I. Diallel analysis of heading time and plant height in F1 progeny. Bot Bull Acad Sin. 1968, 9 (2): 1-9.

    Google Scholar 

  26. Chu QR, Croughan TP: Genetics of plant regeneration in anther culture (AC) of rice (Oryza sativa L.). Review of advances in plant biotechnology, 1985-88: 2nd International Symposium on Genetic manipulation in Crops. Edited by: Mujeeb-kazi A, Sitch LA, CIMMYT and IRRI, Mexico, D. F. 1989, Mexico, and Manila, Philippines, 217-227.

    Google Scholar 

  27. Young JB, Virmani SS: Effects of cytoplasm on heterosis and combining ability for agronomic traits in rice (Oryza sativa L.). Euphytica. 1990, 48: 177-188. 10.1007/BF00037198.

    Article  Google Scholar 

  28. Virmani SS: Heterosis and hybrid rice breeding. Monographs on Theoretical and Applied Genetics. 1994, International Rice Research Institute, Springer-Verlag, 26-30.

    Google Scholar 

  29. IRRI (International Rice Research Institute): Program report for 1993. 1994, International Rice Research Institute, P.O. Box 933, Manila, Philippines, 131-156.

    Google Scholar 

  30. Roach DA, Wulff RD: Maternal Inheritance in Plants. Annual Review of Ecology and Systematics. 1987, 18: 209-235. 10.1146/annurev.es.18.110187.001233.

    Article  Google Scholar 

  31. Tao D, Hu F, Yang J, Yang G, Yang Y, Xu P, Li J, Ye C, Dai L: Cytoplasm and cytoplasm-nucleus interactions affect agronomic traits in japonica rice. Euphytica. 2004, 135 (1): 129-134.

    Article  CAS  Google Scholar 

  32. Pham JL: Genetic diversity and intervarietal relationships in rice (Oryza sativa L.) in Africa. Rice genetics II. 1991, International Rice Research Institute, Manila 1099, Philippines, 55-65.

    Google Scholar 

  33. Hoisington D, Khairallah M, Reeves T, Ribaut JM, Skovmand B, Taba S, Warburton M: Plant genetic resources: What can they contribute toward increased crop productivity?. Proc Natl Acad Sci USA. 1999, 96: 5937-5943. 10.1073/pnas.96.11.5937.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  34. Richards RA: Selectable traits to increase crop photosynthesis and yield of grain crops. Journal of Experimental Botany. 2000, 51: 447-458. 10.1093/jexbot/51.suppl_1.447.

    Article  CAS  PubMed  Google Scholar 

  35. Luo LJ, Li ZK, Mei HW, Shu QY, Tabien R, Zhong DB, Ying CS, Stansel JW, Khush GS, Paterson AH: Overdominant Epistatic Loci Are the Primary Genetic Basis of Inbreeding Depression and Heterosis in Rice. II. Grain Yield Components. Genetics. 2001, 158: 1755-1771.

    PubMed Central  CAS  PubMed  Google Scholar 

  36. Yang RC: Susceptibility of A lines and B lines to bacterial blight (BB). IRRN. 1987, 12 (6): 7-

    CAS  Google Scholar 

  37. Liu KM, Wang LS, Wei LK, Zhu XY, Wu QA: Reaction of rice male sterile cytoplasm of Wild Abortion type to the infection of Pyricularia oryzae. Scientia Agricultura Sinica. 1992, 25 (2): 92-

    Google Scholar 

  38. SAS Institute: SAS/STAT. 1996, SAS Institute, Cary, NY

    Google Scholar 

Download references

Acknowledgements

This research was funded partially by grants from the Yunnan Department of Science and Technology (2005C0011Z) and the National Natural Science Foundation of China (30360054). China National Rice Research Institute (CNRRI) and International Rice Research Institute (IRRI) supplied the plant materials. The authors thank all the investigators who contributed to this study.

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  1. Yunnan Academy of Agricultural Sciences, Food Crops Research Institute, Kunming, 650205, China

    Dayun Tao, Peng Xu, Jiawu Zhou, Xianneng Deng, Jing Li, Wei Deng, Jiangyi Yang, Guifeng Yang, Qiong Li & Fengyi Hu

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Authors' contributions

DT participated in designing the experiment and in drafting the manuscript. PX made some of the nuclear substitution lines and carried out the experiment in Sanya, Hainan. JZ made some of the nuclear substitution lines and carried out the experiment in Kunming, Yunnan. XD carried out the experiment in Sanya, Hainan. JL, assistant to JZ, carried out the experiment in Kunming, Yunnan. WD, assistant to PX and XD, carried out the experiment in Sanya, Hainan. GY made some of the nuclear substitution lines. JY made some of the nuclear substitution lines. QL, assistant to JW, carried out the experiment in Kunming, Yunnan. FH made some of the nuclear substitution lines, participated in designing the experiment, analyzed the data, and participated in drafting the manuscript. All authors have read and approved the final manuscript.

Electronic supplementary material

12863_2009_907_MOESM1_ESM.XLS

Additional file 1:Agronomic-trait data on which Figure 1 and Additional Figures 1 through 6 are based. Means for seven traits expressed by backcross lines representing all combinations of three nuclear and six cytoplasmic genomes at two locations with four replications at each location. (XLS 52 KB)

12863_2009_907_MOESM2_ESM.PPT

Additional file 2:Mean plant height of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for plant height recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 192 KB)

12863_2009_907_MOESM3_ESM.PPT

Additional file 3:Mean panicle length of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for panicle length recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 212 KB)

12863_2009_907_MOESM4_ESM.PPT

Additional file 4:Mean number of panicles per plant of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for number of panicles per plant recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 218 KB)

12863_2009_907_MOESM5_ESM.PPT

Additional file 5:Mean number of spikelets per panicle of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for number of spikelets per panicle recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 206 KB)

12863_2009_907_MOESM6_ESM.PPT

Additional file 6:Mean 1000-grain weight of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for 1000-grain weight recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 216 KB)

12863_2009_907_MOESM7_ESM.PPT

Additional file 7:Mean yield per plot of 18 nuclear-cytoplasm combinations in indica rice. Means and standard errors for yield per plot recorded at two locations, Sanya and Kunming, China, from 18 backcross lines of indica rice representing all combinations of three nuclear and six cytoplasmic genomes. (PPT 204 KB)

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Tao, D., Xu, P., Zhou, J. et al. Cytoplasm affects grain weight and filled-grain ratio in indica rice. BMC Genet 12, 53 (2011). https://doi.org/10.1186/1471-2156-12-53

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