Novel protocol to identify true hybrids in normal oleate x high oleate crosses in peanut 

Chuan Tang Wang*
Shandong Peanut Research Institute
Qingdao, P.R. China
E-mail: chinapeanut@126.com

Shan Lin Yu
Shandong Peanut Research Institute
Qingdao, P.R. China

Shu Wei Zhang
Shandong Peanut Research Institute
Qingdao, P.R. China 

Xiu Zhen Wang
Shandong Peanut Research Institute
Qingdao, P.R. China 

Yue Yi Tang
Shandong Peanut Research Institute
Qingdao, P.R. China 

Jian Cheng Zhang
 Shandong Peanut Research Institute
Qingdao, P.R. China

Dian Xu Chen
Shandong Peanut Research Institute
Qingdao, P.R. China

*Corresponding author

Financial support: The authors thank support from the earmarked fund for Modern Agro-industry Technology Research System (MATRS) Peanut Program (Grant No. nycytx-19), Ministry of Agriculture, China, China Natural Science Foundation (Grant No. 30300224), 863 New and High Technology Project (Grant No. 2006AA10A114), New and High Technology Innovation Foundation of Shandong Academy of Agricultural Sciences (Grant No. 2006 YCX013), and Young Scientists Foundation of Shandong Academy of Agricultural Sciences (Grant No.2007YQN007).

Keywords: identification, NIRS, PCR, peanut, true hybrid.

A novel hybrid identification protocol was developed for F_0:1 peanut seeds resulting from crosses between normal oleate cultivars with wild type FAD2B gene and high oleate genotypes with an A insertion in FAD2B gene. Presence of a series of overlapped peaks in trace file of the PCR product amplified with bF19/R1 primers was an indication of hybridity. This protocol may facilitate high oleate breeding and genetic studies in peanut.

Preferred by food processors and consumers, high oleate peanuts have prolonged shelf life and may decrease bad low density lipoprotein (LDL) cholesterol, while maintaining beneficial high density lipoprotein (HDL) cholesterol (O'Byrne et al. 1997). High oleate is likely to become an indispensable trait of the next generation peanut varieties. Though high in oleate content, the currently available materials have productivity far from acceptable. Incorporating this valuable trait in high yielding adapted cultivars is the endeavor of many peanut breeders worldwide. A simple protocol for identification of true peanut hybrids in normal oleate x high oleate crosses will undoubtedly facilitate this process.

Peanut material

To breed high oleate, Virginia-type peanut varieties for international market and high oleate, high yielding peanut for domestic consumption, four crosses were made between high oleate donors, FB4 and CTWE, 2 peanut lines developed by us, and normal oleate, high yielding peanut cultivars, Huayu 31, Huayu 22 and 08-test-A2 (Table 1). Crossing was carried out by workers with minimal training according to the standard procedure described by Yu et al. (2008). Ten seeds (F_0:1, hybridity unknown) were randomly selected from each cross for hybrid identification. Seed serial numbers 1-10, 11-20, 21-30 and 31-40 were from Huayu 31 x FB4, Huayu 22 x CTWE, 08-test-A2 x CTWE and 08-test-A2 x FB4, respectively.

Cloning and sequencing of FAD2B/fad2B gene in parental genotypes

DNA templates were prepared from immature leaflets in peanut seeds as described by Wang et al. (2009). Gene-specific PCR primers, bF19/R1 (Patel et al. 2004), were used to amplify the FAD2B/fad2B gene. The PCR mixture (50 µl) contained 25 µl of Tiangen 2 x Taq platinum Master Mix (Tiangen Biotech, Beijing, China), 5 µl of DNA template, 2 µl of forward and reverse primers (10 µM) each. The PCR program was 95ºC for 6 min, followed by 35 cycles of 94ºC for 30 sec，53ºC for 1 min，and 72ºC for 2 min, and a final extension of 74ºC for 4 min. The PCR program was run on a Biometra Tgradient thermal cycler (Biometra, Göttingen, Germany). The PCR products were purified, ligated into a pBS-T vector, and used in heat shock transformation with chemically competent TOP10 E. coli cells (Tiangen Biotech, Beijing, China). White colonies harboring plasmids with inserts of expected size identified by colony PCR were sequenced on an ABI 3730XL DNA sequence using the M13 forward and reverse primers. Translation and alignment of DNA sequences were completed with the Lasergene^TM DNAStar package (DNASTAR, Madison, USA).

Amplification of FAD2B/fad2B gene to identify true hybrids

PCR templates were prepared from a slice of cotyledonary tissue (Yu et al. 2010). The PCR mixture (50 µl) consisted of 5 µl of DNA template, 2 µl of bF19/R1 (10 µM) primers each (Patel et al. 2004), and 25 µl of Tiangen 2 x Taq PCR Master Mix (Tiangen Biotech, Beijing). The thermal cycling profile and PCR machine were the same as mentioned above. After checking for presence of amplification bands on agarose gel, the PCR products were purified and then sequenced on an ABI 3730XL DNA sequencer using the bF19 primer. The trace files were viewed with Finch TV1.4.0 (Geospiza Inc., Seattle, USA).

Cloning and sequencing of FAD2B/fad2B gene in parental genotypes

With bF19/R1 primers, all of the parental genotypes, viz., normal oleate peanut varieties, Huayu 22, Huayu 31 and 08-test-A2, and high oleate peanut lines, FB4 and CTWE, produced PCR products of expected size. Positive colonies were obtained through colony PCR.

Multiple alignment of the resultant DNA sequences and the Arachis hypogaea L. FAD2B sequence deposited in GenBank (GenBank acc# AF272950) showed that in high oleate parental lines, there was an A insertion immediately after the 521 base counting from the bF19 primer, corresponding to the position after 441 in coding region of the FAD2B gene (Figure 1), which caused a frameshift and a truncated protein. The mutant type of FAD2B, fad2B, was the same as those described by Yu et al. (2008) and Chu et al. (2009).

Amplification of FAD2B/fad2B gene(s) to identify true hybrids

With bF19/R1 primers, all the 40 seeds from the 4 crosses yielded PCR products of expected size. Two types of trace files were shown in Figure 2 and Figure 3.

Huayu 31, Huayu 22 and 08-test-A2 were confirmed to have wild type FAD2B genes, whereas FB4 and CTWE had a loss-of-function FAD2B gene (fad2B). Characterized by presence of a series of overlapped peaks in trace files, true hybrids (F_0:1) can be easily identified by visual inspection of trace files (Figure 2 and Figure 3). Among the 40 seeds tested with sequencing, 4, 5, 5 and 1 seeds were identified as true hybrids for Huayu 31 x FB4, Huayu 22 x CTWE, 08-test-A2 x CTWE and 08-test-A2 x FB4, respectively, and the rest seeds were false hybrids (Table 1). On average, true hybrids accounted for 37.5% of the F_0:1 seeds.

For detection of wild and mutant type FAD2A/FAD2B genes, cleaved amplified polymorphic sequences (CAPS) markers for both homologous genes (Chu et al. 2007; Chu et al. 2009) and real-time PCR marker for wild and mutant alleles of FAD2B (Barkley et al. 2010) have also been developed. These protocols need restriction enzymes or a qPCR machine. More recently, Chen et al. (2010) reported development of a simple allele-specific PCR assay for both genes. However, in our lab, conducted with a PCR machine of different type, this assay was not as successful as described by the developers. In contrast, our protocol to detect mutant allele of FAD2B is straightforward and more reliable, as long as sequencing facilities are readily accessible. Since there are many companies providing sequencing service and the cost per run is constantly going down, the present protocol suits the need from poorly equipped labs without a DNA sequencer.

True hybrids in peanut may also be identified by morphological features, though it is not always reliable, and sometimes time-consuming (Gomez et al. 2008). Other molecular tools, such as isozymes profiling and DNA marker system, have been successfully used to distinguish true hybrids from selfs (Lacks and Stalker, 1993; Gomez et al. 2008; Li et al. 2009); for a specific cross combination, screening for informative isozymes/primers are absolutely necessary. Our protocol, however, is widely applicable to crosses between normal oleate cultivars and high oleate genotypes with 441_442insA in FAD2B gene, since no normal oleate peanut genotype with such an insertion in FAD2B gene has thus far been identified in world peanut germplasm collections (Chen et al. 2010). It seems that there is no need to change primers and PCR thermal cycling profiles for different cross combinations.

The present protocol has been successfully used to establish F₂ segregating populations (F_1:2 seeds) resulting from normal oleate x high oleate crosses, and robust near infrared spectroscopy (NIRS) calibration equations have been developed for predicting oleic (R² = 97.20%), linoleic (R² = 96.90%), and palmitic acids (R² = 93.39%) in intact single peanut seeds (Chuan Tang Wang unpublished). The hybridity of the F_0:1 seeds was supported by NIRS analysis. Oleate contents in the true F_0:1 seeds, as predicted by NIRS, were essentially intermediate relative to oleate in parental genotypes (data not shown), an indication that NIRS may have some potential in this regard, even though variation in oleate content of single intact peanut seeds of a specific cultivar does exist.

Loss-of-function FAD2A and FAD2B genes (fad2A and fad2B) are considered to be the major genes responsible for high oleate trait of peanut, but there are also other genes that influence oleate content (Isleib et al. 2006). The present protocol is of significance to studies on the genetics of high oleate in peanut and the effects of FAD2A, FAD2B and additional genes, and is helpful to peanut breeders interested in developing high oleate peanut cultivars as well. Of course, this protocol can also be used to appraise the performance of workers in hybridizing peanuts.

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