1. Agricultural College and Research Institute, TamilNadu Agricultural University, Madurai, India
2. Centre for Plant Breeding &Genetics, TamilNadu Agricultural University, Coimbatore, India
3. Dharmalingam, Agricultural College &Research Institute, Trichy, India
Author
Correspondence author
Rice Genomics and Genetics, 2015, Vol. 6, No. 4 doi: 10.5376/rgg.2015.06.0004
Received: 25 Mar., 2015 Accepted: 30 Apr., 2015 Published: 07 May, 2015
More than half of the world’s population, especially women and children in the developing countries suffer from micronutrient malnutrition especially deficiency in iron and zinc. Micronutrient malnutrition problems increased the interest of researchers to increase the mineral contents (Fe and Zn) in cereals to ensure adequate attainment of dietary minerals. A lot of variability does exist for micronutrients (Fe, Zn, Vitamin A, etc.) content and bioavailability in many crops including rice. The current study was conducted to assess the variability for iron and zinc content along with quality traits in dehusked rice grains to identify mineral-rich families. This study was conducted with the major objectives of analysis of genetic variability for quality traits for grain iron and zinc content. Based on mean, GCV & PCV, heritability and genetic advance, it was understood that the progenies of ADT 37 x IR68144-3B-2-2-3 would be more useful for improving grain iron content with the desirable quality traits viz., kernel length, kernel breadth after cooking. Similarly TRY (R) 2 x Mapillaisamba segregants could be used for improving the grain zinc content and breadth wise expansion ratio.
Rice is the life and the prince among cereals as this unique grain helps to sustain two thirds of the world’s population. Asia is the biggest rice producer, accounting for 90 per cent of the world’s production and consumption of rice (Anonymous, 2007). It is considered as the main staple food for more than 50 per cent of the world’s population. Rice provides 75 per cent of the calories and 55 per cent of the protein in the average daily diet of the people although it has an incomplete amino acid profile and comprises confined amount of essential micronutrients (Bhuiyan et al., 2002). The per capita consumption of rice is very high ranging from 62 to 190 kg/year (Graham et al., 1999). To be healthy, human beings require more than 20 mineral elements and more than 40 nutrients, particularly vitamins and essential amino acids, all of which can be supplied by an appropriate diet (Philip and Martin, 2005). However, human diets often lack one or more of essential nutrients and cause micronutrient malnutrition. Micronutrient malnutrition is recognized as a massive and rapidly growing public health issue especially among poor people living on an unbalanced diet dominated by a single staple grain such as rice. Among the major micronutrient deficiencies common in rice consuming countries , iron and zinc deficiencies (the so called “hidden hunger”), affect over three billion people worldwide, mostly in developing countries (Welch and Graham, 2004). Plant breeding to enhance the nutrient quality of staple food crops holds promise for a low cost and sustainable approach to alleviate the problem of micronutrient malnutrition among the poorest segments of the population of developing countries. This approach has been called biofortification. Biofortification reduces malnutrition by breeding essential micronutrients into staple crops. This approach bridges the fields of human nutrition, crop science and public health to develop a set of highly sustainable nutrition interventions in a cost-effective manner. Exploiting the genetic variation in crop plants for micronutrient content is one of the most powerful tools to change the nutrient balance of a given diet on a large scale.
1 Results and Discussion
In the present investigation ADT 37 x IR68144-3B-2-2-3 showed high mean value for the characters viz., kernel length, kernel breadth after cooking, iron content. TRY (R) 2 x Mapillaisamba had high mean value for the characters viz., zinc content, breadth wise expansion ratio. The genotypic and phenotypic coefficient of variability were low in both the crosses for the most of the traits viz., kernel length, kernel breadth, kernel L/B ratio, kernel length after cooking, kernel breadth after cooking, linear elongation ratio and breadth wise expansion ratio (Table 1). It indicated that all the crosses might have attained homozygosity in F4 itself for these traits. These results were in accordance with Nandeshwar et al. (2010) whostudied F2 progenies which were derived from the crosses IR-62 × Samba Mashuri and Kunti x Dudheswar and the report of Kumar et al. (2006) in rice F2 generation for kernel length. Umadevi et al. (2010) recorded low genotypic and phenotypic coefficient of variability for kernel breadth in 110 rice genotypes.The findings of Vanaja and Babu (2006) recorded low genotypic and phenotypic coefficient of variability for kernel length after cooking and kernel breadth after cooking, breadth wise expansion ratio in 10 quality parameters in set of 56 high yielding diverse rice genotypes which is corroborates the current investigation. For iron and zinc content moderate GCV and PCV was observed in F5 generation. Hence, these traits need one or more generations in order to attain homozygosity. These results were in parallel with the findings of Kalaimaghal (2011) who observed moderate GCV and PCV for iron content in the in F2 and F3 the cross ADT37 × IR68144-3B-2-2-3.
.png)
Table 1 Variability studies for quality traits in rice with high iron and zinc content in F4 & F5 Generation
|
High heritability coupled with high genetic advance was observed in ADT37 x IR68144-3B-2-2-3 only for iron and zinc content, except TRY(R) 2× Mapillaisamba which showed high heritability with moderate genetic advance. Hence, these traits were least influenced by environment and mostly governed by additive gene action. Therefore, there is scope for improvement of iron and zinc content by exercising selection pressure on these two characters. These results were in agreement with Shanmuga Sundara Pandian (2007), Purusothaman (2010) and Aswini Shamak et al. (2011) in F4 and F5 generation. Low heritability with low genetic advance as percentage of mean was observed for kernel length, kernel breadth and kernel L/B ratio in all the crosses in both the generations. The findings of Jayasree (2007) and Umadevi et al. (2010) in genotypes observed medium to high heritability with high genetic advance as percentage of mean for kernel length after cooking, kernel breadth after cooking, linear elongation ratioand breadth wise expansion ratio which in contrast with the result of current investigation. Based on mean, GCV & PCV, heritability and genetic advance, it was understood that the progenies of ADT 37 x IR68144-3B-2-2-3 would be more useful for improving grain iron content with the desirable quality traits viz., kernel length, kernel breadth after cooking. Similarly TRY (R) 2 × Mapillaisamba segregants could be used for improving the grain zinc content and breadth wise expansion ratio.
2 Material and Methods
Seeds of F3 generation of two Cross combinations generated from Anbil Dharmalingam, Agricultural College &Research Institute, Trichy. viz., ADT 37 × IR68144-3B-2-2-3, TRY (R) 2 × Mapillaisamba were utilized as the experimental material in the present study. Among the parents viz., TRY (R) 2 and ADT 37 are high yielding commercial varieties and IR68144-3B-2-2-3 is a iron donor and Mapillaisamba is a zinc donor which were used in earlier hybridization programme for introgression of high iron and zinc contributing genes. The experiment was conducted at Agricultural College and Research Institute, Madurai. The F4 generation was raised during August to November, 2011 and F5 generation during December 2011 to April 2012 respectively. The F4 progenies were raised along with their parents in randomized block design with two replications. A total of five families were selected from each cross combination based on high iron and zinc content in F3 population. For each family, 75 seedlings per replication were raised with a spacing of 20 cm between the rows and 15 cm between the plants. Each family had five rows of 15 single plants each. The recommended agronomic practices were followed throughout the crop growth period. Five single plants per family per replication were randomly selected and forwarded as single plant progeny row in F5 generation. The mean data after computing for each character subjected to standard method of analysis of variance following Panse and Sukhatme (1967), phenotypic and genotypic coefficient of variation, heritability (broad sense) and genetic advance as per cent of mean were estimated by the formula as suggested by Burton (1952) and Johnson et al. (1955). The following quality traits are
2.1 Kernel Length (KL)
Ten unbroken hulled kernels with their tips intact from each genotype were measured for their length using Vernier Callipers. Average of length was taken in millimeters.
2.2 Kernel breadth (KB)
Ten unbroken hulled kernels with their tips intact from each genotype were measured for their breadth using Vernier Callipers. Average of breadth was taken in millimeters.
2.3 Kernel length / breadth ratio (KLBR)
The ratio between kernel length and breadth was estimated.
2.4 Kernel length after cooking (KLAC)
Ten randomly selected whole milled rice kernels were taken in a labelled test tube and soaked in water for ten minutes. The tubes were placed in a water bath maintained at boiling temperature (100℃) for 20 minutes. After cooking, the cooked kernels (intact on both ends) were measured using a graph paper mounted in a glass frame and the average kernel length after cooking was expressed in millimeters.
2.5 Kernel breadth after cooking (KBAC)
Ten randomly selected whole milled rice kernels were taken in a labelled test tube and soaked in water for ten minutes. The tubes were placed in a water bath maintained at boiling temperature (100℃) for 20 minutes. After cooking, the cooked kernels (intact on both ends) were measured using a graph paper mounted in a glass frame and the average kernel breadth after cooking was expressed in millimeters.
2.6 Linear elongation ratio (LER)
The ratio of mean length of cooked rice to mean length of milled rice was computed as linear elongation ratio (Juliano and Perez, 1984).
.png)
2.7 Breadth wise expansion ratio (BER)
The ratio of mean breadth of cooked rice to mean breadth of milled rice was computed as breadth wise expansion ratio
.png)
The zinc and iron content were determined by using Atomic Absorption Spectrophotometer as suggested by Jackson (1973). All the statistical analysis was done by using GENRES statistical software GEN STAT 2004. Aswini Samak., N.R., Shailaja Hittalmani., N. Shashidhar and Hanumareddy Birada., 2011, Exploratory studies on genetic variability and genetic control for protein and micronutrient content in F4 and F5 generation of rice. Asian. J. of Plant Sci., 10 (7): 376-379
http://dx.doi.org/10.3923/ajps.2011.376.379
Anonymous., 2007, Agriculture and Industry Survey. 17 (11): 18-20
Burton., G.W. 1952, Quantitative inheritance in grasses. In: Proc. 6 th Inter Grassland Congr., 1: 277- 283
Bhuiyan., N.I., D.N.R., Paul and M.A., Jabbar., 2002, Feeding the extra millions by 2025 challenges for rice research and extension in Bangladesh. A keynote paper presented on National Workshop on Rice Research and Extension held on 29-31 January 2002 at BRRI, Gazipur. p9
Graham R.D., Senadhira D., Beebe S., Iglesias C., and Monsterio I., 1999, Breeding for micronutrient density in edible portions of stable food crops: conventional approaches, Field Crops Res., 60:57-80
http://dx.doi.org/10.1016/S0378-4290(98)00133-6
Jackson., M.L., 1973, Soil and plant analysis. Prentice Hall of India Private Limited, New Delhi
Jayasree., 2007, Characterization of landraces, cultivars and new plant types of rice for quantitative and grain quality traits. M.Sc., (Ag.) Thesis (Unpubl.), TNAU, Coimbatore
Kalaimaghal., R. 2011, Studies on genetic variability of grain iron and zinc content in F2, F3 generation of rice (Oryza sativa L.). M.Sc. (Ag.) Thesis (Unpubl.), TNAU, Coimbatore
Kumar., S., A.S., Gautam and C., Chandal. 2006, Estimates of genetic parameters for quality traits in rice (Oryza sativa L.) in mid hills of Himachal Pradesh. Crop Res., 32 (2): 206-208
Nandeshwar., B.C., S. Pal, B.K., Senapati and D.K. De. 2010, Genetic variability and character association among biometrical traits in F2 generation of some Rice crosses. Electron. J. Plant Breed., 1(4): 758-763
Panse., V.G. and Sukhatme, P.V., 1961, Statistical methods for agricultural workers. 2nd edition, Indian Council. Agric. Res., New Delhi. pp. 22
Purusothaman., R. 2010, Genetic analysis for high iron and zinc content in rice (Oryza sativa L.) grains.M.Sc., (Ag.) Thesis (Unpubl.), TNAU, Coimbatore
Shanmuga sundarapandian., G. 2007, Studies on diversity and Genotype × Environment interaction for micronutrient content in rice (Oryza sativa L.). M.Sc.,(Ag.) Thesis. (Unpubl.), TNAU, Coimbatore
Umadevi., M., P. Veerabadhiran, S. Manonmani and P. Shanmugasundaram., 2010, Physico-chemical and cooking characteristics of rice genotypes. Electron. J. Plant Breed., 1 (2):114-123
Vanaja., T and L.C., Babu. 2006, Variability in grain quality attributes of high yielding rice varieties (Oryza sativa L.) of diverse origin. J. Trop. Agric., 44 (1-2): 61-63
Welch., R.M. and R.D., Graham. 2004, Breeding for micronutrients in staple food crops from a human nutrition perspective. J. Exp. Bot., 55: 353-364
http://dx.doi.org/10.1093/jxb/erh064
