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Article

Molecular and Cytogenetic Characterization of New Wheat—Dasypyrum breviaristatum Derivatives with Post-Harvest Re-Growth Habit

1
School of Life Science and Technology, University of Electronic Science and Technology of China, Chengdu 610054, China
2
Crop Research Institute, Sichuan Academy of Agricultural Sciences, Chengdu 610066, China
*
Author to whom correspondence should be addressed.
Submission received: 25 August 2015 / Revised: 10 November 2015 / Accepted: 18 November 2015 / Published: 27 November 2015
(This article belongs to the Special Issue Genetic Diversity for Crop Improvement)

Abstract

:
A novel Dasypyrum species, Dasypyrum breviaristatum, serves as a valuable source of useful genes for wheat improvement. The development and characterization of new wheat—D. breviaristatum introgression lines is important to determine the novel gene(s) on specific chromosome(s). We first used multi-color fluorescence in situ hybridization (FISH) to identify the individual D. breviaristatum Vb chromosomes in a common wheat—D. breviaristatum partial amphiploid, TDH-2. The FISH patterns of D. breviaristatum chromosomes were different from those of D. villosum chromosomes. Lines D2146 and D2150 were selected from a cross between wheat line MY11 and wheat—D. breviaristatum partial amphiploid TDH-2, and they were characterized by FISH and PCR-based molecular markers. We found that D2150 was a monosomic addition line for chromosome 5Vb of D. breviaristatum, while D2146 had the 5VbL chromosome arm translocated with wheat chromosome 5AS. Molecular marker analysis confirmed that the introduced D. breviaristatum chromosome 5VbL translocation possessed a duplicated region homoeologous to 5AS, revealing that the 5AS.5VbL translocation may not functionally compensate well. The dwarfing and the pre-harvest re-growth habits observed in the wheat—D. breviaristatum chromosome 5Vb derivatives may be useful for future development of perennial growth wheat lines.

1. Introduction

The genus Dasypyrum (or Haynaldia) consists of two species, Dasypyrum villosum and D. breviaristatum. Cytological and molecular evidence suggest significant genomic diversification between the two species, and therefore the genome symbols of D. villosum and D. breviaristatum were assigned to V and Vb, respectively [1,2]. Recently, Baum et al. [3] suggested the genome constitution of tetraploid D. breviaristatum as VVVbVb (2n = 4x = 28) based on the evolutionary analysis of the nr5S DNA multi-gene family. Both Dasypyrum species displayed several agronomical important traits including those of disease resistance, high protein quality and drought tolerance, which offer valuable resources for wheat improvement [4,5]. The D. villosum species has been extensively hybridized to wheat, and several disease resistance genes have been successfully transferred to wheat [6,7,8]. With the aim to transfer useful genes from D. breviaristatum into wheat, we produced a wheat—D. breviaristatum partial amphiploid and several wheat—D. breviaristatum introgression lines by chromosome manipulation [9,10,11].
Precise identification of the alien chromosomes and wheat-alien recombinant chromosomes is essential for investigation of evolution and utilization of novel chromatin in wheat breeding. Chromosome C-banding and fluorescence in situ hybridization (FISH) are powerful techniques to visualize alien chromatin in wheat-alien hybrids [12,13]. The large heterochromatic C-bands of D. villosum chromosomes enable the identification of the D. villosum chromosomes and their rearrangement in the wheat background [14,15]. Recently, Zhang et al. [16] established a FISH karyotype of D. villosum chromosomes by probes of pSc119.2, pAs1, 45S and 5SrDNA. Meanwhile, the simple sequence repeat (GAA)n can be used as a FISH probe to characterize the individual D. villosum chromosomes [17]. However, D. breviaristatum chromosomes displayed less telomeric heterochromatin and generally had different C-banding patterns compared to those of D. villosum [18] The detailed karyotype of D. breviaristatum chromosomes needs to be established by molecular and cytogenetic methods.
Development of “perennial wheat” has been proposed as a potential method for sustainability of agricultural production, food security, and environmental quality [19]. Many Triticeae species have been used as donors of perennial growth habit to improve wheat [20,21]. As a perennial Dasypyrum species, D. breviaristatum has a strong perennial character with a post-harvest regrowth (PHR) habit, which could be transferred to a wheat background. Here we aimed to establish the karyotype of D. breviaristatum chromosomes in a wheat background, and characterize the novel wheat—D. breviaristatum introgression lines by using multicolor-fluorescence in situ hybridization and molecular markers.

2. Materials and Methods

2.1. Plant Materials

D. breviaristatum accession PI 546317 (genome VVVbVb, 2n = 4x = 28) was obtained from the National Small Grains Collection at Aberdeen, Idaho, USA. The wheat—D. breviaristatum partial amphiploid TDH-2 (genome AABBVbVb, 2n = 6x = 42) was as described by Yang et al. [9]. Triticum turgidum cv. Jorc-69- D. villosum amphiploid ABV (genome AABBVV, 2n = 6x = 42) was developed and provided by Prof. Hua-Ren Jiang at Sichuan Agricultural University, China [22]. Line D2146 and D2150 was obtained from the BC1F4 generation of a cross between wheat line MY11 and TDH-2.

2.2. Fluorescence in Situ Hybridization (FISH)

Seedling root tips were collected and pretreated in water at 0 °C for 24 h and fixed in ethanol-acetic acid (3:1) for conventional squashes. The nitrous oxide treated root-tip followed by enzyme digested drop method was also reported by Tang et al. [23]. FISH with the LTR probe pDbH12 was used to detect the Dasypyrum genome in a wheat background as reported by Yang et al. [24]. The synthesized probes Oligo-pSc119.2, Oligo-pTa535, Oligo-(GAA)6 were used in the FISH analysis [23]. The hybridization and detection protocols were as described by Fu et al. [25]. Microphotographs of FISH chromosomes were taken with an Olympus BX-51 microscope equipped with a DP-70 CCD camera.

2.3. Molecular Marker Analysis

DNA was extracted from young leaves of D. breviaristatum, TDH-2, ABV, lines D2146, D2150 and Triticum aestivum cv. “Chinese Spring” (CS). PCR-based Landmark Unique Gene (PLUG) primers and EST based primers were designed according to Ishikawa et al. [26] and Fang et al. [27], respectively. Polymerase chain reaction (PCR) was performed in an Icycler thermalcycler (Bio-RAD Laboratories, Emeryville, CA, USA) in a 25 μL reaction, containing 10 mmol Tris-HCl (pH 8.3), 2.5 mmol MgCl2, 200 μmol of each dNTP, 100 ng template DNA, 0.2 U Taq polymerase (Takara, Japan) and 400 nmol of each primer. The cycling parameters were 94 °C for 3 min for denaturation; followed by 35 cycles at 94 °C for 1 min, 55 °C for 1 min, 72 °C for 2 min; and a final extension at 72 °C for 10 min. The amplified products were separated by 8% PAGE gel as described by Hu et al. [28].

2.4. Agronomic Performance Observations

Field agronomic trait observations were performed at the Xindu Experimental Station, Chengdu, China during the 2012–2015 wheat-growing season. A post-harvest re-growth (PHR) habit displays a second phase of tiller initiation after the sexual cycle of the first phase is completed [29]. After harvesting, the 40 cm stubble of the lines was left in the field for evaluation of re-growth. Either a crown or tiller emerging from the soil surface was taken to be regrowth, with regrowth expressed as a percentage of PHR measured one month after harvest.

3. Results

3.1. FISH Karyotype of D. breviaristatum Chromosomes in TDH-2

In order to establish the FISH karyotype of D. breviaristatum chromosomes, a partial amphiploid between wheat—D. breviaristatum [9], the mitotic metaphase chromosomes of TDH-2 that were hybridized using the Oligo-pSc119.2, Oligo-pTa535, Oligo-(GAA)7 and pDb12H probes through sequential multicolor-FISH (Figure 1). As shown in Figure 1A, strong hybridization signals of the Dasypyrum specific probe pDb12H [23] were observed on all 14 chromosomes of TDH-2, indicating that they are D. breviaristatum chromosomes. Subsequently, Oligo-pSc119.2 and Oligo-pTa535 probes were also used to identify the D. breviaristatum chromosomes (temporarily designed from A to G) of the same metaphase of the TDH-2 partial amphiploid (Figure 1B). We found that the signals using Oligo-pSc119.2 probe were mainly located on the terminal sites of one arm in four pairs of chromosomes (C, D, F and G), and both arms in two pairs of chromosomes (B and F) (Figure 1B and Figure 2A). The hybridization signals of Oligo-pTa535 were distributed on all the chromosome arms of D. breviaristatum, including signals at the terminal, sub-terminal or interstitial sites and occasionally at centromeric positions (Figure 1B and Figure 2A). The Oligo- (GAA)7 probe hybridized to five pairs of D. breviaristatum chromosomes (A-B, D, F-G) at their centromeric regions or sub-terminal regions, while two pairs of chromosomes (C and E) were free of Oligo- (GAA)7 hybridization sites (Figure 1C and Figure 2A). Based on the distribution of the above four probes, the FISH karyotype of the seven pairs of D. breviaristatum chromosomes in TDH-2 was obtained (Figure 2B). Compared with the reported FISH karyotype of wheat and other Triticeae genomes [16,17,24,25], we conclude that FISH can precisely identify the D. breviaristatum chromosomes in a wheat background.
Figure 1. Sequential fluorescence in situ hybridization FISH of wheat—D. breviaristatum partial amphiploid (TDH-2) with probes pDb12H (A), Oligo-pSc119.2 (green) and Oligo-pTa535 (red) (B) and Oligo-(GAA)7 (C) (red). The bars indicated 10 µm.
Figure 1. Sequential fluorescence in situ hybridization FISH of wheat—D. breviaristatum partial amphiploid (TDH-2) with probes pDb12H (A), Oligo-pSc119.2 (green) and Oligo-pTa535 (red) (B) and Oligo-(GAA)7 (C) (red). The bars indicated 10 µm.
Genes 06 01242 g001
Figure 2. Karyotype (A) and ideogram (B) of D. breviaristatum chromosomes presents in the wheat—D. breviaristatum partial amphiploid (TDH-2).
Figure 2. Karyotype (A) and ideogram (B) of D. breviaristatum chromosomes presents in the wheat—D. breviaristatum partial amphiploid (TDH-2).
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3.2. FISH of D2150 and D2146

The probes Oligo-pSc119.2, Oligo-pTa535, Oligo-(GAA)7 and pDb12H were used to identify the chromosomes in metaphase spreads of wheat—D. breviaristatum D2146 and D2150 lines (Figure 3A). FISH with the pDb12H probe revealed that D2150 had 43 chromosomes including a D. breviaristatum chromosome (Figure 3A). The sequential FISH using Oligo-Sc119.2 and Oligo-pTa535 (Figure 3B), as well as the Oligo-(GAA)6 (Figure 3C), suggested that in the D2150 line, the added D. breviaristatum chromosome was identical to the chromosome G of TDH-2 (Figure 2). FISH by pDb12H indicated that D2146 carried a pair of wheat—D. breviaristatum translocated chromosomes (Figure 3D). The FISH with probes Oligo-pSc119.2 and Oligo-pTa535 (Figure 3E), and Oligo-(GAA)6 (Figure 3F), indicated that the translocated chromosome in D2146 line showed one weak Oligo-pSc119.2 band at the end of the short arm while the long arm of D. breviaristatum showed both a strong pSc119.2 and faint Oligo-pTa535 sites at the terminal regions. We deduced that the short arm showed the typical FISH pattern of 5AS and the long arm resembled that of chromosome G of D. breviaristatum.
Figure 3. FISH of wheat—D. breviaristatum derivative lines. (AC) wheat-monosomic addition line for chromosome 5Vb of D. breviaristatum (D2150) and (DF) 5AS.5VbL translocation line (D2146). The probes pDb12H (A,D) and Oligo-pSc119.2 (B,E) are showed in green. The probes Oligo-pTa535 (B,E) and Oligo- (GAA)7 (C,F) are showed in red. Arrows and stars show the D. breviaristatum chromatin, and bars indicate 10 µm.
Figure 3. FISH of wheat—D. breviaristatum derivative lines. (AC) wheat-monosomic addition line for chromosome 5Vb of D. breviaristatum (D2150) and (DF) 5AS.5VbL translocation line (D2146). The probes pDb12H (A,D) and Oligo-pSc119.2 (B,E) are showed in green. The probes Oligo-pTa535 (B,E) and Oligo- (GAA)7 (C,F) are showed in red. Arrows and stars show the D. breviaristatum chromatin, and bars indicate 10 µm.
Genes 06 01242 g003aGenes 06 01242 g003b

3.3. Molecular Marker Analysis

In order to determine the linkage group of the D. breviaristatum chromatin in D2146, molecular markers based on the syntenic regions between wheat EST and rice genomic DNA sequences were used to identifying alien fragments corresponding to the wheat linkage group(s) [30,31,32]. A total of 12 PLUG markers from wheat homologous group 5 [26] and 22 Hordeum californicum chromosome 5Hc specific markers [27] were used. The markers were tested on D2146 and its parents (MY11 and TDH-2) as well as D. breviaristatum. We found that 13 markers generated specific bands from D. breviaristatum and TDH-2. Three markers were assigned to the short arm and 10 markers were located on long arm of D. breviaristatum chromosome 5Vb (Table 1). As shown in Figure 4, the PLUG markers TNAC1554 and TNAC1567 amplified fragments from the long arm of chromosomes 5A, 5B, and 5D of common wheat CS. The chromosome 5AL specific fragments were absent in D2146, while the D. breviaristatum specific bands appeared in D2146. These results suggested that the 5AS chromosome arm was translocated to the 5VbL. However, marker TNAC1485 simultaneously amplified 5AS and 5VbL specific bands in the D2146 translocation line (Figure 4A). As shown in Figure 5, we conclude that D2146 translocation line may contain a putative duplicated fragment of homologous group 5 from wheat and Dasypyrum chromosomes 5Vb.
Table 1. The PCR primers used in this study.
Table 1. The PCR primers used in this study.
MarkersHomoeologous RelationshipPrimer SequencesEnzymesDasypyrum Specific Bands
TNAC 1485 a5AS,5BS, 5DSF: CCCAAGTTCACTAACTTCGTTGTaq I5VbL
R: AAATAGTCCTGCATATCTCCTGT
TNAC 1497 a5AS,5BS, 5DSF: ATCAAACCTGACGGTGTTCAGTaq I5VbS
R: CATGCAGACTACAGGTCCAGA
TNAC1503 a5AS,5BS, 5DSF: TGAGGTTGGTTCTCATCTGGATaq I5VbS
R: CGTTGGAAACAATCTGAATGG
TNAC1588 a5AS,5BS, 5DSF: AAATCAGCAGGTGGCCAGTATTaq I5VbS
R: AAATGGCGCACCATACTCAAG
TNAC1540 a5AL,5BL, 5DLF: AACCTCAAGCACTGTCAGCATHea III5VbL
R: TTGCAGATCCTCTCAATCTCG
TNAC 1554 a5AL,5BL, 5DLF: TTGCTAGCTCAGCACAGTTTGTaq I5VbL
R: TTCTTGGTCACTCTGAGCGTA
TNAC1559 a5AL,5BL, 5DLF: AAACAAGGCCCTGAAACACTTHea III5VbL
R: CATTGTCAGGCTATGGGACAT
TNAC 1567 a5AL,5BL, 5DLF: ATGTTGGCTTTATACCAATGCTaq I5VbL
R: AGGTGCGGCTTCACTATCTTT
TNAC 1618 a5AL,5BL, 5DLF: GTTGGCTGTTGATGGTAAGGATaq I5VbL
R: GGAGGCCACCAACTAATGTTT
BE445873 b5AL,5BL,5DLF: ATCTCGACAAAGATCAAGCA-5VbL
R: CGAGAAGTTCCATCTCATTG
BE445380 b5AL,5BLF: GCTACCACAGTTGCTACAGG-5VbL
R: ATCGACGTAACACGAATCAC
BE604833 b5ALF: GCAGATTCACCCACTCTGTA-5VbL
R: ATACGCGGTCACATCATAAA
BE443610 b5AL,5BL,5DLF: ACCAATGAAGGACCATCTCT-5VbL
R; CATTTCTCAGCTTGTCCAAC
(Note: a Ishikawa et al. [26]; b Fang et al. [27]).
Figure 4. PCR amplification of molecular markers in wheat—D. breviaristatum lines. (A) TNAC1485; (B) TNAC1554; (C) BE443610; (D) TNA1567; (E) BE445380 and (F) BE604833. CS: “Chinese Spring” wheat; Db: D. breviaristatum; TDH-2: wheat—D. breviaristatum partial amphiploid; D2146: 5AS.5VbL translocation line; ABV: Triticum turgidum, D. villosum amphiploid. The arrows indicate the D. breviaristatum specific bands.
Figure 4. PCR amplification of molecular markers in wheat—D. breviaristatum lines. (A) TNAC1485; (B) TNAC1554; (C) BE443610; (D) TNA1567; (E) BE445380 and (F) BE604833. CS: “Chinese Spring” wheat; Db: D. breviaristatum; TDH-2: wheat—D. breviaristatum partial amphiploid; D2146: 5AS.5VbL translocation line; ABV: Triticum turgidum, D. villosum amphiploid. The arrows indicate the D. breviaristatum specific bands.
Genes 06 01242 g004
Figure 5. FISH karyotypes and molecular markers distributed on chromosomes 5A, 5Vb, and 5AS.5VbL translocation. The stars indicates the duplicated markers on chromosome 5AS.5VbL.
Figure 5. FISH karyotypes and molecular markers distributed on chromosomes 5A, 5Vb, and 5AS.5VbL translocation. The stars indicates the duplicated markers on chromosome 5AS.5VbL.
Genes 06 01242 g005

3.4. Agronomic Traits Observation

A set of agronomic traits were measured on 15 plants of the D. breviaristatum 5Vb monosomic addition line, 5AS.5VbL translocation line, wheat MY11 and the wheat—D. breviaristatum partial amphiploid (Table 2). Relative to the MY11 recurrent parent, all 5Vb lines had reduced plant height, suggesting that chromosome 5Vb carries a dwarfing gene(s) expressed in the wheat background. No significant differences were found for the length of spikes in the 5Vb monosomic addition line, 5AS. 5VbL translocation line and the wheat control. The 5AS. 5VbL translocation line had a decreased number of spikelets per spike and a 1000-kernel weight compared to its wheat parent indicating that the translocation may have an unfavorable effect on grain yield relative to wheat lines.
The wheat—D. breviaristatum partial amphiploid (TDH-2), D. breviaristatum 5Vb monosomic addition (D2150), and 5AS. 5VbL translocation line (D2146) were found to have PHR habits under field conditions, while the parent MY11 has no PHR habit (Table 2). This result indicates that D. breviaristatum 5VbL may contain a gene(s) responsible for the PHR habit in annual wheat background.
Table 2. Agronomical traits of wheat—D. breviaristatum 5V b derivatives.
Table 2. Agronomical traits of wheat—D. breviaristatum 5V b derivatives.
GenotypePlant Height (cm)Length of Spike (cm)No. of SpikeletNo. of Spikes1000-Kernel Weight (g)Re-Growth Score
MY1186.5 ± 1.2a10.5 ± 0.5b20.6 ± 0.2a4.2 ± 0.2b40.4 ± 1.0a0
TDH-270.0 ± 4.8b14.2 ± 0.5a16 .8 ± 0.3b7.5 ± 0.5a16.5 ± 0.6c86
D214665.0 ± 3.0b10.0 ± 0.4b15 .0 ± 1.5b3.0 ± 0.5b31.7 ± 1.7b56
D215077.3 ± 3.5ab11.0 ± 0.5b19.1 ± 1.5a3.9 ± 0.5b39.7 ± 0.8a78
(Note: Values with the same letter in the same column do not differ significantly at p < 0.05).

4. Discussion

Fluorescence in situ hybridization (FISH) and genomic in situ hybridization (GISH) have been most useful techniques for investigating wheat—alien derivatives [13,33]. However, the conventional FISH protocols based on probe labeling, hybridization and detection were somewhat time-consuming and expensive [34,35]. The simpler and more efficient technique based on synthetic labeled oligonucleotides combined with non-denaturing FISH (ND-FISH) analysis were recently developed [24,36,37,38]. The synthetic oligonucleotides have been successfully used in FISH experiments, including the SSRs oligonucleotides and conserved nucleotides representing repetitive sequences, for karyotyping wheat, barley and rye chromosomes [39,40,41]. Recently, chromosome-specific painting in plant species using synthetic bulked oligonucleotides was also established [42]. In the present study, we detected the wheat and Dasypyrum chromatin using synthetic labeled oligonucleotides by ND-FISH with chromosome preparation of both a conventional squash method (Figure 1 and Figure 3A–C) and a nitrous oxide treated drop method (Figure 3D–F). In combination with Dasypyrum specific LTR probe pDb12H [23], we used the synthetic oligonucleotide probes, Oligo-pTa535, Oligo-pSc119.2, and Oligo-(GAA)7 [23], to develop a high resolution FISH karyotype of D. breviaristatum chromosomes in TDH-2. The FISH karyotypes can be used to the precisely locate the Dasypyrum chromatin in a wheat background. Comparing the FISH patterns of D. breviaristatum chromosomes present in the wheat—D. breviaristatum partial amphiploid (TDH-2) we found that the added D. breviaristatum chromosome in the D2150 line was identical to chromosome G of TDH-2 and that the fragment of D. breviaristatum present in the D2146 translocation line resembled the long arm of the chromosome G. Grosso et al. [17] used the simple sequence repeat (GAA)n as a FISH probe, to characterize the individual D. villosum chromosomes except for chromosome 1V. Recently, Zhang et al. [16] investigated the FISH distribution patterns of three repeated DNA sequences, pSc119.2, pAs1, 45S rDNA and 5S rDNA in the individual D. villosum chromosomes of D. villosum wheat addition and translocation lines. Compared with the FISH pattern of D. villosum chromosomes by Zhang et al. [16], we found that the seven pairs of D. breviaristatum chromosomes in the wheat—D. breviaristatum partial amphiploid displayed unique FISH patterns. Two pairs of D. breviaristatum chromosomes were lacking of (GAA)n signals (Figure 2), the other five D. breviaristatum chromosomes pairs showed weaker (GAA)n signals than those of D. villosum chromosomes [17]. Moreover, the terminal regions of the short arms of three D. breviaristatum chromosomes showed strong pSc119.2 signals, while almost all D. villosum chromosome short arms have the pSc119.2 signals [16]. The results suggested that the accumulation of the repetitive sequences in D. breviaristatum chromosomes was less than in D. villosum chromosomes. The results were consistent with the evolutionary studies on the D. breviaristatum and D. villosum chromosomes by cytogenetic and molecular evidence [43,44], and supported the idea that D. breviaristatum was ancestral to the D. villosum species [3,5].
The production of compensating Robertsonian translocations is an important step for the evaluation of the breeding value of alien genetic materials [8]. Liu et al. [34] reported a set of wheat—D. villosum compensating Robertsonian translocations including a line TA5638 with T5DL·5V#3S translocation between 5V and 5D. Zhang et al. [45] irradiated whole-arm wheat—D. villosum T5VS·5DL translocation line, and produced six homozygous small segment translocation lines with different fragment sizes of 5VS, and a 5VS-6AS·6AL terminal translocation. In the present study, we produced a line (D2150) with a D. breviaristatum 5Vb chromosome in monosomy and a homozygous T5AS·5VbL translocation line (D2146). Based on the molecular markers analysis, nine of 10 markers validated the introgression of 5VbL. However, the specific amplification of marker TNAC1485 appeared in both chromosome 5AS and 5VbL arms (Figure 4A). It is suggested that the homologous duplication of the segments has occurred in this region in the T5AS·5VbL translocation lines. Recently, Li et al. [32] reported that the rye (Secale cereale L.) chromosome 5RL also contained homologous 5S wheat segments. These authors found that TNAC1485 marker was also located on rye chromosome 5RL. It is likely that the rearrangement occurred between the ancestral group 5 in Secale and in Dasypyrum chromosomes. Further evidence is needed to clarify the detail changes, possibly by inversion or centromeric movement during evolution by comparative genomic studies between wheat and related species.
Based on the agronomic traits evaluated (Table 2) it is likely that incomplete compensation of chromosome 5AS.5VbL in the D2146 line may cause inferior agronomic traits, such as reduced grain weight and spikelet number, compared with the wheat parent. Amphiploids and addition lines among wheat and some perennial species have shown the post-harvest re-growth habit (PHR) which has been investigated to produce potentially perennial wheat [46]. So far, wheat—Thinopyrum partial amphiploids [20,21] and wheat—Th. elongatum chromosome 4E addition lines [29] have been reported to express the PHR traits from these alien species in a wheat background [47]. As a perennial species, D. breviaristatum showed a strong perennial growth habit. The wheat—D. breviaristatum partial amphiploid (TDH-2) and the 5Vb derived lines (D2146 and D2150) also showed the PHR trait which putatively originated from D. breviaristatum parent. These results suggest that the PHR trait could be controlled by genes located on D. breviaristatum 5VbL chromosome arm. The lines with PHR habits will be useful for the development of perennial grain crops for feeding the animals.

5. Conclusions

Dasypyrum breviaristatum was a perennial species with a post-harvest re-growth character. Based on the molecular and cytogenetic studies, novel wheat—D. breviaristatum 5Vb chromosome addition and 5AS.5VbL translocation line were characterized. New D. breviaristatum 5Vb specific molecular markers were also produced. The wheat—D. breviaristatum derivatives and molecular markers may be favorable for future use of D. breviaristatum resources for development of perennial growth wheat lines.

Acknowledgments

We thank the National Natural Science Foundation of China (No. 31171542, 31101143, 31201203) for the financial support.

Author Contributions

Zujun Yang and Guangrong Li conceived of and designed the experiments. Hongjun Zhang, Dan Gao, Donghai Li and Jie Zhang performed the experiments. Zujun Yang, Ennian Yang and Guangrong Li analyzed the data. Zujun Yang wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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MDPI and ACS Style

Zhang, H.; Li, G.; Li, D.; Gao, D.; Zhang, J.; Yang, E.; Yang, Z. Molecular and Cytogenetic Characterization of New Wheat—Dasypyrum breviaristatum Derivatives with Post-Harvest Re-Growth Habit. Genes 2015, 6, 1242-1255. https://0-doi-org.brum.beds.ac.uk/10.3390/genes6041242

AMA Style

Zhang H, Li G, Li D, Gao D, Zhang J, Yang E, Yang Z. Molecular and Cytogenetic Characterization of New Wheat—Dasypyrum breviaristatum Derivatives with Post-Harvest Re-Growth Habit. Genes. 2015; 6(4):1242-1255. https://0-doi-org.brum.beds.ac.uk/10.3390/genes6041242

Chicago/Turabian Style

Zhang, Hongjun, Guangrong Li, Donghai Li, Dan Gao, Jie Zhang, Ennian Yang, and Zujun Yang. 2015. "Molecular and Cytogenetic Characterization of New Wheat—Dasypyrum breviaristatum Derivatives with Post-Harvest Re-Growth Habit" Genes 6, no. 4: 1242-1255. https://0-doi-org.brum.beds.ac.uk/10.3390/genes6041242

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