Discrimination of haploid and diploid maize kernels via multispectral imaging

The use of doubled haploids (DHs) in maize has become ubiquitous in maize breeding programmes as it allows breeders to go from cross to evaluation in as little as 2 years. Two important aspects of the in vivo DH system used in maize are as follows: (i) the identification of haploid progeny and (ii) doubling of the haploid genome to produce fertile inbred lines. This study is focused on the first step. Currently, identification of maize haploid progeny is performed manually using the R1‐nj seed colour marker. This is a labour‐intensive and time‐consuming process; a method for automated sorting of haploids would increase the efficiency of DH line development. In this study, six inbred lines were crossed with the maternal haploid inducer ‘RWS/RWK‐76’ and a sample of seed was sorted manually for each line. Using the VideometerLab 3 system, spectral imaging techniques were applied to discriminate between haploids and hybrids. Using DNA markers to confirm the haploid/diploid state of the tested seed, for the majority of genotypes haploid identification was possible with over 50% accuracy.     

Dicamba and growth condition effects on doubled haploid production in durum wheat crossed with maize

Doubled haploid plants are useful in genetic studies and plant breeding, but a consistent and satisfactory frequency of production has been difficult to achieve in durum wheat. Triticum turgidum L., using the maize pollen method. The objective of this study was to develop an objective method of producing doubled haploids in durum wheat. Plant growing and handling conditions, aspects of hormone treatments, wheat genotype and pollen source were considered. The number of caryopses, embryos, haploids, doubled plants and doubled plants that set seed were measured. Although growth conditions, pollen source, method of handling plants and wheat genotype are important considerations, the type of hormone was found to be most significant in the production of doubled haploid plants. When 50mg/l dicamba was substituted for 100 mg/l 2,4‐D the number of doubled haploids per spike increased from 0.2 for the best 2,4‐D treatment to 1.3 for the dicamba treatment. This increased frequency was largely attributed to an increase in the number of caryopses generated for each spike emasculated and from an increased frequency of germination of embryos to haploid plantlets. The best production of caryopses was 0.41 caryopses per florest with 2,4‐D. The best production of haploids per 100 florets was 12 with dicamba and 1.65 with 2,4‐D. The frequency of one doubled haploid per emasculated spike through the use of dicamba is a practical level for generating populations for genetic studies.     

Conditions favouring doubled haploid breeding over conventional breeding of self-fertilizing crops

Summary Monte Carlo computer simulation was used to investigate the conditions favouring doubled haploid breeding over conventional breeding of self-fertilizing crops. Two different systems of doubled haploid breeding and three systems of conventional breeding were compared for two criterion parameters, i.e., the probability of obtaining desirable genotypes and the expected genetic advance of selected lines. It was inferred that the efficiency of production of haploid and doubled haploid plants primarily determines the success of the doubled haploid breeding method. In doubled haploid breeding, about 1/5, hopefully 1/2 as many test plants need to be raised as in conventional breeding to achieve the same level of success. With this condition begin satisfied, the doubled haploid breeding method can efficiently be used when one or more of the following conditions are met: (i) a relatively small number of loci, presumably ten of less, is involved with the breeding objective concerned, (ii) desirable alleles are recessive to undesirable ones at most, if not all, of the segregating loci, and (iii) the genes are not strongly linked. It was confirmed that the doubling of haploids can better be applied to selected F₂ plants rather than to F₁ plants.     

Germplasm enhancement of maize: a look into haploid induction and chromosomal doubling of haploids from temperate‐adapted tropical sources

The allelic diversity (AD) project of the Germplasm Enhancement of Maize (GEM) programme utilized the double haploid (DH) breeding method to expedite development and release of lines derived from 300 exotic maize races. Using 18 races in this study, differential effects on haploid induction rates (HIRs) and doubling rates (DRs) by the recurrent parents PHB47 and PHZ51, the elevation that the race is traditionally grown at, and by the race itself were addressed in this study. Races from the AD project were grouped by elevation of their origin, high, middle or low altitude. Six races per elevation were randomly selected and backcrossed using both recurrent parents to generate 36 populations. Ten replications were randomized in a complete randomized design for two growing seasons. The recurrent parent effect was significant, with PHB47 having a higher HIR than PHZ51. Effect of elevation was significant with higher HIR associated with low‐elevation origin, and race also proved to be significant. Effects of elevation, recurrent parent and race were not significant for DR.     

The effect of spikelet position on the success frequencies of wheat haploid production using the maize cross system

Barbela is an old Portuguese landrace of wheat that is highly genetically heterogeneous. Different Barbela populations when subjected to aluminium stress show variable levels of tolerance. In order to study the inheritance of this character, doubled haploid (DH) lines were developed. These DH were obtained by intergeneric crosses of 14 different lines of Barbela with maize. During this process the efficiency of the technique was evaluated and suggestions for its improvement were obtained. Several parameters were studied in the crosses: % of crossability, % of embryos per florets pollinated and % of embryos per seed set. The different genotypes of Barbela showed significant variation for the parameters analysed. When the reciprocal crosses were analysed, no differences were found, indicating that cytoplasm differences do not influence the parameters of DH production. However, different spikelet positions (lower, middle and upper) gave highly significant differences in all parameters analysed. Highest success frequencies were obtained for pollinated spikelets in the middle of the spike. This can indicate that concentrating on the middle part of the spike can increase the frequency of DHs obtained using inter generic crosses of wheat with maize. This revised version was published online in August 2006 with corrections to the Cover Date.     

Haploid differentiation in maize kernels based on fluorescence imaging

A new fluorescence‐based method for inbred haploid differentiation in maize kernels was developed by utilizing the R1‐nj colour marker in combination with fluorescence microspectroscopy and imaging. Seven inbred lines with varying R1‐nj expression were used in this study. The fluorescence response of the diploid kernels at the embryonic dye spot was shown to simultaneously exhibit lower intensity and occur at a higher wavelength than the fluorescence of the dye‐lacking haploid embryos. Intensity and area thresholds were applied to fluorescence images to sort the haploids from mixed sample populations, and sorting efficiencies of greater than 80% were achieved in all seven inbred lines (with values greater than 90% for five lines). The potential for high‐throughput sorting when fluorescence imaging is combined with existing technologies for seed handling as well as high sorting efficiency may make fluorescence a viable and promising alternative to current sorting methods for some inbred lines.     

Early diagnosis of ploidy status in doubled haploid production of maize by stomata length and flow cytometry measurements

Reliable discrimination of haploid (H), doubled haploid (DH) and crossing (C) plants in early growth stages could streamline DH production in maize. By detecting in early growth stages undesirable sterile H plants and undesirable heterozygous C plants, a large proportion of resources required for DH production could be saved. The goal of this study was to evaluate the effectiveness of early classification of plants in growth stages V3‐V4 as H, DH or C in the context of DH production using flow cytometry and stomata length. As the reference classification, we used a field score based on plant phenotype commonly applied in DH production and research. Our results show that identification of misclassified C seeds is possible because the overlap in distributions of stomata length between H&DH and C plants is small and the association between flow cytometry and the reference field score is high. In contrast, overlap between H and DH distributions is substantial. Consequently, the main application we see for these classification methods in early growth stages is the identification of C seedlings.     

A data transfer method for improving seed identification of maize (Zea mays) haploid breeding based on genetic similarity

Maize haploid breeding technology is able to identify haploid seeds non‐destructively, rapidly and at low cost with the help of Near‐infrared (NIR) spectral analysis. However, due to the hybridization of numerous parents and the low production rate of haploid, the haploid data collection becomes a burden for engineering this technology. Biologically, there are considerable similarities between the progeny of the same female parent and different male parents. Based on this advantage, similar spectral data can be transferred when the NIR technology is employed. A revised method of Transfer adaptive boost (TrAdaBoost) is proposed to improve identifying for the backpropagation neural network (BPNN) classifier. To avoid the negative transfer, a screening thresh is used to select out similar data, and the amount of these data are limited to join current training. The results show that the identification performances are improved significantly when the data amount is small. This method shows a high ability to make the seed identification more convenient for engineering maize haploid breeding.     

利用小麦ⅹ玉米诱导小麦单倍体形成的研究

摘 要：利用小麦(Triticum aestivum L.)与玉米(Zea mays L.)进行远缘杂交,是获得小麦单倍体的一条重要途径,也是获得双单倍体(Double haploid ,DH)植株、构建小麦遗传群体的重要途径之一。本研究为创建小麦抗吸浆虫DH群体,在温室条件下对5个小麦抗、感吸浆虫杂交组合进行了单倍体诱导试验。结果表明：小麦不同基因型对诱导单倍体胚形成有较大影响;小麦授粉后2,4-D适宜的点药时间为6－36小时;适宜的2.4-D药液为 10－30mg/L;授粉后适宜的剥胚培养时间为14－16天,授粉后茎秆离体培养有较好的诱导效果,培养温度以20-250C为宜。本文提出了在温室条件下高效诱导小麦单倍体植株的方法及条件。     

Properties of maternal haploid maize plants and potential application to maize breeding

Summary Presented are the results of a two-year study of haploid maize plants in the field. The haploids were produced with the aid of inducer line ZMS. In total, 604 and 1030 haploids were obtained and studied in the first and second years, respectively. Tassels of haploid plants were found to be almost completley sterile. Fertility of ears was studied by pollinating them with the pollen from diploid inbred lines, the cross resulting in almost all of the haploid ears carrying kernels. On average 27.4 kernels per ear of haploid plant were obtained in the first year of study and 26.3 in the second. These gave rise to normal diploid plants. This property allows genotypes selected at the level of haploid plants to be involved in breeding process. Unusual plants were found among haploids, phenotypically resembling homozygous lines. It was assumed that the plants had resulted from spontaneous chromosome doubling in haploids. The results of comparative studies of progenies of unusual plants and inbred lines derived from the same synthetic population are presented.     

Segregation of genetic markers among wheat doubled haploid lines derived from wheat x maize crosses

Summary Wheat doubled haploid (DH) lines were produced from the F₁ hybrid, Fukudo-komugi x Oligo Culm, through intergeneric crosses between wheat and maize. F₂ plants and 203 DH lines were analyzed for the segregation of the eight genetic markers, namely, grain proteins, grain esterases, GA-insensitivity and glume traits. The segregation in the F₂ plants fitted to the expected ratios. No deviation was observed among the DH lines, either, except for the glume pubescence. The result indicates the absence of correlation between the markers investigated and the efficiency of embryo formation in the DH lines.     

我国玉米地方种质的单倍体诱导和加倍特性研究

双单倍体(doubled haploid,DH)育种技术具有加速育种进程的突出优势,已成为玉米育种关键性核心技术并在国外广泛应用.本试验选用47份玉米地方种质,进行单倍体诱导和单倍体加倍特性研究.结果表明,47份玉米地方种质材料之间杂交诱导的拟单倍体率有显著差异,介于1.64％～14.50％之间,平均为5.95％.种植12份玉米地方种质的拟单倍体籽粒进行田间鉴定,标记鉴定准确率介于40.2％～82.3％之间,校正单倍体诱导率介于2.33％～6.45％之间,表明玉米遗传背景影响到籽粒标记的表达,单倍体诱导率有明显差异.将15份玉米地方种质拟单倍体于冬季在海南田间种植,加倍授粉株率介于2.7％～27.2％之间,加倍结实株率介于0.7％～8.9％.说明我国玉米地方种质的遗传多样性丰富,单倍体诱导率和加倍率具有明显差异,利用DH育种技术可以拓宽和加强我国玉米地方种质在玉米育种中的利用.     

Genetic dissection of haploid male fertility in maize (Zea mays L.)

Haploid genome doubling is a key limiting step of haploid breeding in maize. Spontaneous restoration of haploid male fertility (HMF) provides a more promising method than the artificial doubling process. To reveal the genetic basis of HMF, haploids were obtained from the offspring of 285 F_2:3 families, derived from the cross Zheng58 × K22. The F_2:3 families were used as the female donor and Yu high inducer No. 1 (YHI‐1) as the male inducer line. The rates of HMF from each family line were evaluated at two field sites over two planting seasons. HMF displayed incomplete dominance. Transgressive segregation of haploids from F_2:3 families was observed relative to haploids derived from the two parents of the mapping population. A total of nine quantitative trait loci (QTL) were detected, which were distributed on chromosomes 1, 3, 4, 7 and 8. Three major QTL, qHMF3b, qHMF7a and qHMF7b were detected in both locations, respectively. These QTL could be useful to predict the ability of spontaneous haploid genome doubling, and to accelerate the haploid breeding process by introgression or aggregation of those QTL.     

Efficient haploid and doubled haploid production from unfertilized ovule culture of gentians (Gentiana spp.)

Factors affecting reliable plant regeneration from unfertilized ovule culture of gentians (Gentiana spp.) were examined. Cold pretreatment (4°C) of flower buds enhanced or maintained production of embryo-like structure (ELS). When 43 genotypes were surveyed in two different labs, 40 of them produced ELSs ranging from 0.01 to 26.5 ELSs per flower bud. No ELSs could be obtained in three genotypes. A significant correlation (r = 0.64) was observed between the number of ELS per flower and the frequency of responding flower buds. Eight genotypes of G. triflora, which were used as common materials in two different labs, produced ELSs in both labs. The ploidy levels of a total of 1,515 regenerated plantlets were determined, revealing that the majority of these plants consisted of haploids (57.9%) and diploids (34.3%). However, the frequency of haploids and diploids was different between G. triflora and G. scabra, and G. triflora showed higher frequencies of haploids than G. scabra. When haploids were treated with oryzalin for chromosome doubling, diploids and tetraploids were obtained. These results demonstrate that the unfertilized ovule culture technique of gentians is a powerful tool for obtaining haploids and DHs because of its reproducible and reliable nature and application to a wide range of genotypes.     

Chromosome doubling of haploid maize seedlings using nitrous oxide gas at the flower primordial stage

In maize, inbred lines are used for the production of hybrid varieties. Corn breeders and researchers have considered using haploids to develop inbred lines; however, this procedure has not been practically applied because of the inefficiency of chromosome doubling of maize haploid seedlings. In this report, a procedure has been developed to overcome this difficulty. Maize haploid seedlings obtained from eight different genotypes were treated with nitrous oxide gas (2 days at 600 kPa). Treatment at the six‐leaf stage (flower primordia formation stage) significantly increased the occurrence of fertile sectors on both tassels and ears so that approximately half (44%) of the treated haploids produced kernels after self‐pollination. In the control, only 11% of haploids produced selfed kernels owing to spontaneous chromosome doubling. A strong genotypic effect on the occurrence of fertile sectors after the treatment was observed. This procedure can be used for inbred line development in maize breeding programmes.     

Segregation distortion for agronomic traits in doubled haploid lines of barley

Four barley doubled haploid populations were produced by anther culture from the reciprocal crosses between two six‐row barley cultivars, ‘Plaisant’ and ‘Orria’; the doubled haploid lines (DHLs) derived from each cross were subsequently assigned to weak or vigorous populations according to the weak or vigorous nature of the originating embryos. Well‐formed embryos at day 25 on the induction medium were considered vigorous, whereas embryos maturing later were considered weak. The classification of vigorous and weak was closely associated with the ratio of green to albino plantlets regenerated. A random set of 25 DHLs from each of the four populations were selected for field testing in a replicated trial. Furthermore, a second set consisting of a total of 454 unreplicated DHLs from the four populations were also field assessed for grain yield. Distortion during in vitro culture may impede regeneration of a random array of microspores from a given cross, and may bias genetic estimates of specific trait/marker association in genetic studies. However, no significant differences were detected in this study among the four populations for days to heading, height, grain yield and thousand‐kernel‐weight when measured on the replicated trial of 100 DHLs, nor for grain yield in the second collection of 454 entries. This suggests that the likelihood of producing improved agronomic pure lines is independent of the direction of crossing and, more importantly, independent of the time when embryos matured in the induction media, at least for these particular six‐row cultivars and for the anther culture method used.     

Review of doubled haploid production in durum and common wheat through wheat × maize hybridization

Production of doubled haploids (DHs) is an important methodology to speed the process of breeding and development of mapping populations in crops. The procedure for DH production includes two major steps: haploid induction and chromosome doubling. In recent years, wide hybridization between wheat and maize has become a main approach for haploid production in wheat. In this method, the maize chromosomes are completely eliminated during the early development of the hybrid seeds after wheat spikes were pollinated with maize pollen. Numerous wheat cultivars and mapping populations have been developed using wheat–maize hybridization. In this study, we review the procedures of DH production of durum and common wheat via wide hybridization with maize, the factors which affect the efficiency of DH production, and the mechanism of selective elimination of the maize genome during the early development of the hybrid embryos. We also report a highly efficient protocol for DH production in durum and common wheat, which was established based on the optimal conditions for each of the factors that affect the efficiency of DH production.     

同一基础材料的玉米双单倍体(DH)系配合力的分析

利用高频玉米单倍体诱导系,对选系材料M35/F35的F1代进行诱导获得大量单倍体籽粒,经自然加倍获得一批纯合双单倍体(DH)系,用测验系京24组配杂交组合分析DH系的配合力表现。结果表明,来源于同一基础材料的不同DH系之间,配合力差异较大,部分DH系的配合力比亲本增加,说明采用单倍体育种可以选育到高配合力的优良玉米自交系,组配出优良品种,从而加快育种进程,应用前景广阔。     

Genetic analysis of total glucosinolate in crosses involving a high glucosinolate Indian variety and a low glucosinolate line of Brassica juncea

Analysis of the glucosinolate content and composition by high‐pressure liquid chromatography indicated that varieties of Brassica juncea bred and grown in India have a high glucosinolate content characterized by the presence of 2‐propenyl (allyl) and 3‐butenyl as the major and 4‐pentenyl as the minor fractions. In contrast, the B. juncea germplasm from other countries is characterized by the presence of 2‐propenyl as the major glucosinolate fraction, trace amounts of 3‐butenyl and a total lack of the 4‐pentenyl types. In order to transfer the low glucosinolate trait to Indian B. juncea, the inheritance of total glucosinolates was investigated using doubled haploid (DH) populations derived from F1 (DH₁) and BC₁ (BC₁DH) of a cross between ‘Varuna’ (the most widely cultivated high glucosinolate variety of India) and ‘Heera’ (a non‐allyl type low glucosinolate line). A total of 752 DH₁ and 1263 BC₁DH gave rise to seven and 11 low glucosinolate (containing less than 18 μmol/g seed) individuals, respectively. On the basis of the frequency of the low glucosinolate individuals, the total glucosinolate was found to be under the control of seven genes. There was presence of both allyl and non‐allyl types in DH₁ and BC₁DH low‐glucosinolate individuals and absence of 3‐butenyl glucosinolate in some of the BC1DH low glucosinolate individuals, indicating segregation for these fractions in the population. The size of the segregating DH population proved to be crucial for precise determination of the number of genes controlling the trait. Because of the large number of genes involved, incorporation of low glucosinolate trait in Indian B. juncea should be approached through doubled haploid (DH) breeding.