Are stomatal area and stomatal density reliable traits for identification of doubled haploids in maize?

Ribeiro, Mariana Rodrigues; Trindade, Roberto dos Santos; Souza, Isabel Regina Prazeres de; Carneiro, Andréa Almeida; Azevedo, Tácila Cristina de; Guimarães, Lauro José Moreira; Chaves, Saulo Fabrício da Silva; Dias, Luiz Antônio dos Santos

doi:10.1590/1984-70332022v22n2a16

Abstract

To meet the demands of the production chain, breeding programs need to reduce the time for selection and development of higher yielding maize genotypes. This involves application of new strategies, such as the use of the doubled haploid lines. We evaluated the use of stomatal area and density in distinguishing doubled haploids (DH) from false positive (FP) plants derived from nine tropical source populations. We selected four DH plants and two FP plants for identification of DH through leaf anatomy in the populations, in each group. Data on stomatal area and density were considered in a completely randomized model in a factorial scheme (populations and genotypes) and analyzed by restricted maximum likelihood. There were statistically significant effects of populations and genotypes for both traits. For stomatal density, the population by genotype interaction was not verified. Stomatal density proved to be efficient for distinguishing DH and FP for use in selection of doubled haploids.

Keywords:
Zea mays; leaf anatomy; doubled haploid technology; false positive

INTRODUCTION

Maize is the main cereal crop grown worldwide and, together with soybean, constitute the two main agricultural products in Brazil. Brazilian maize production in the 2021/22 season is estimated at 114 million metric tons. The country is the third largest producer worldwide and the second largest exporter of the crop. World production will reach 1.2 billion tons in 2021/22 (USDA 2022USDA - United States Department of Agriculture2022 World agricultural production. Circular series WAP 3-22). The large production of maize in Brazil shows its importance in human and animal nutrition and as an input in industry, which leads to greater demand and, possibly, larger planted area.

To meet the demands of the production chain, plant breeding programs need to reduce the time for selection and development of higher yielding maize genotypes that are resistant to stresses and have traits that facilitate management. This involves application of new strategies, such as the use of the technology of doubled haploid (DH) lines (Xu et al. 2017XuYLiPZouCLuYXieCZhangXPrasannaMBOlsenMS2017 Enhancing genetic gain in the era of molecular breeding. Journal of Experimental Botany 68:2641-2666, Chaikam et al. 2019ChaikamVMolenaarWMelchingerAEBoddupalliPM2019 Doubled haploid technology for line development in maize: Technical advances and prospects. Theoretical and Applied Genetics 132:3227-3243). The aim of the DH technology is to reduce the time necessary for obtaining homozygous lines by one and a half year (three generations), allowing uniform and genetically stable lines to be acquired. This advantage of the DH technology has led seed companies to use it on a broad scale to reduce time and costs in releasing hybrids (Liu et al. 2016LiuZWangYRenJMeiMFreiUKTrampeBLübberstedtTOrtizR2016 Maize doubled haploids. Plant Breed Review 40:123-166). Thus, DH technology has become a focus of research in companies and universities (Couto et al. 2013CoutoEGDODavideLMCBustamanteFDOPinhoRGVSilvaTN2013 Identification of haploid maize by flow cytometry, morphological and molecular markers. Ciência e Agrotecnologia 37:25-31).

Visual analysis is the first parameter used in the identification of haploid embryos. It is based on the phenotypic marker expressed by the gene R1-navajo (R1-nj), which codifies the anthocyanin pigmentation of the endosperm and embryo of maize seeds (Nanda and Chase 1966NandaDKChaseSS1966 An embryo marker for detecting monoploids of maize (Zea Mays L.) 1. Crop Science 6:213-215). Visual analysis allows selection of seeds that will give rise to possible haploids from the embryos that are white, having genes only from the source genotype (Prasanna et al. 2012PrasannaBM2012 Doubled haploid technology in maize breeding: An overview. In Prasanna BM, Chaikam V and Mahuku G (eds) Doubled haploid technology in maize breeding: Theory and practice. CIMMYT, Mexico, p. 1-8).

In spite of its efficiency for initial selection of haploids, visual analysis of seeds is subject to inaccuracy in the process of identification. Such inaccuracy is due to the R1-nj marker, which can be completely inhibited or segregate in the grain in the cross of haploidy induction, due to the existence of alleles that interfere in the anthocyanin synthesis pathway, which may occur with greater frequency in populations of tropical origin (Chaikam et al. 2015ChaikamVNairSKBabuRMartinezLTejomurtulaJBoddupalliPM2015 Analysis of effectiveness of R1-nj anthocyanin marker for in vivo haploid identification in maize and molecular markers for predicting the inhibition of R1-nj expression. Theoretical and Applied Genetics 128:159-171). Thus, it is necessary to evaluate traits that allow later identification and exclusion of false positives (FP), that is, distinguishing plants whose seeds were erroneously identified as haploids (through errors in selection or inhibition in the formation of anthocyanin in the embryo), from putative haploids, which would be the true haploid individuals, correctly identified, promoting reduced expenditures on inputs, labor, and space (Choe et al. 2012ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401, Souza et al. 2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ).

Various traits have been analyzed for selection of haploids in maize, such as the color of seminal roots (Prassana et al. 2012PrasannaBM2012 Doubled haploid technology in maize breeding: An overview. In Prasanna BM, Chaikam V and Mahuku G (eds) Doubled haploid technology in maize breeding: Theory and practice. CIMMYT, Mexico, p. 1-8, Chaikam et al. 2016ChaikamVMartinezLMelchingerAESchipprackWBoddupalliPM2016 Development and validation of red root marker-based haploid inducers in maize. Crop Science 56:1678-168), oil content in the embryo (Melchinger et al. 2014MelchingerAESchipprackWFriedrich UtzHMirditaV2014 In vivo haploid induction in maize: identification of haploid seeds by their oil content. Crop Science 54:1497-1504), seed weight (Smelser et al. 2015SmelserABlancoMLübberstedtLübberstedtTTSchechertAVanousAGardnerC2015 Weighing in on a method to discriminate maize haploid from hybrid seed. Plant Breeding 134:283-285), seedling vigor (Ribeiro et al. 2018RibeiroCBPereiraFDCNóbrega FilhoLDRezendeBADiasKODGBrazGTRuyMCSilvaMBCenziGTechioVHSouzaJCD2018 Haploid identification using tropicalized haploid inducer progenies in maize. Crop Breeding and Applied Biotechnology 18:16-23), and length of the shoot and roots (Chaikam et al. 2017ChaikamVLopezLAMartinezLBurgueñoJBoddupalliPM2017 Identification of in vivo induced maternal haploids in maize using seedling traits. Euphytica 213:1-9). Often, analytical procedures such as flow cytometry (Couto et al. 2013CoutoEGDODavideLMCBustamanteFDOPinhoRGVSilvaTN2013 Identification of haploid maize by flow cytometry, morphological and molecular markers. Ciência e Agrotecnologia 37:25-31, Han et al. 2016HanYGuYZhangACLoYH2016 Imaging technologies for flow cytometry. Lab on a Chip 16:4639-4647, Ribeiro et al. 2018RibeiroCBPereiraFDCNóbrega FilhoLDRezendeBADiasKODGBrazGTRuyMCSilvaMBCenziGTechioVHSouzaJCD2018 Haploid identification using tropicalized haploid inducer progenies in maize. Crop Breeding and Applied Biotechnology 18:16-23) and anatomical analysis of the stomata (Choe et al. 2012ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401, Souza et al. 2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ) are also used. These methods make it possible to confirm the haploidy of plants in the seed or seedling stages and eliminate diploid plants that were not excluded by the previous parameters.

Anatomical analysis to identify haploid plants is an effective methodology and can be performed in the initial phases of plant development, with rapid results at low-cost (Souza et al. 2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ). Analyzing the length of stomatal guard cells is a methodology used for discrimination of ploidy, because it has been correlated with DNA content in various species. Changes in the level of ploidy in plants result in changes in the size and anatomy of their organs and cells, and such changes can be identified by microscopy. In the Clematis heracleifolia chromosomal duplication with a colchicine solution generated individuals with greater stomatal length and width (Wu et al. 2013WuPRenJLiLChenS2014 Early spontaneous diploidization of maternal maize haploids generated by in vivo haploid induction. Euphytica 200:127-138). In in vitro chromosomal duplication of unfertilized ovules of Chrysanthemum sp., greater stomatal length was observed in doubled haploids than in individual haploids (Wang et al. 2014WangHDongBJiangJFangWGuanZLiaoYChenSChenF2014 Characterization of in vitro haploid and doubled haploid Chrysanthemum morifolium plants via unfertilized ovule culture for phenotypical traits and DNA methylation pattern. Frontiers in Plant Science 5:738). Furthermore, crossing the male-sterile wheat line (Triticum sp.) with the haploid inducer maize genotype generated haploid plants that had guard cells that were longer than the guard cells of diploid control plants (Zhang et al. 2014ZhangWWangKLinZSDuLPMaHLXiaoLLYeXG2014 Production and identification of haploid dwarf male sterile wheat plants induced by corn inducer. Botanical Studies 55:1-8).

The aim of the study was to evaluate the efficiency of use of stomatal area and density in distinguishing DH from FP plants derived from tropical source populations of maize, increasing the efficiency for obtaining and selecting DH lines.

MATERIAL AND METHODS

The trial and its evaluations

The trial was conducted at Embrapa Milho e Sorgo, in Sete Lagoas, Minas Gerais, Brazil, from December 2017 to July 2019. We evaluated DH and FP lines derived from nine source populations, obtained from biparental crosses between elite lines of the breeding program of Embrapa Milho e Sorgo, being five source populations from the Flint heterotic group and four from the Dent group. The F₁ crosses were made only between lines of the same heterotic group. After that, the F₁ source populations were self-fertilized, resulting in the F₂ generation. Then the lines of the F₂ generation were self-fertilized to obtain the F₃ generation. Finally, haploidy was induced in an isolated lot for each source population (F₁, F₂, and F₃). However, haploids were not obtained from all the generations, due to losses in the field, resulting in 16 populations of DH lines (Table 1).

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Table 1
Doubled haploid lines evaluated in the experiment, their generations (F₁, F₂, F₃) and heterotic groups

The field for haploidy induction was set up in December 2017 by sowing the nine source populations in individual rows interspersed with the haploid gynogenetic inducer hybrid TAIL P1 × TAIL P2, in a 1:1 proportion. The haploidy inducer field was isolated by 1000 m from other maize crops in the vicinity. Seeds were mechanically sown in 4.2-m-long rows and between-row spacing of 0.70 m. The crop treatments in the induction field were performed as recommended by Amaral Filho et al. (2005Amaral FilhoJPRDFornasieri FilhoDFarinelliRBarbosaJC2005 Row spacing, population density and nitrogen fertilization in maize. Revista Brasileira de Ciência do Solo 29:467-473). At anthesis, all the plants of the source populations had been detasseled so as to allow only the pollen derived from the haploidy inducers to be in the field.

Manual harvest of the field was carried out in April 2018, and ears from each source population were placed in bags with tags identifying origin and heterotic group. Seeds were selected through the R1-navajo (R1-nj) marker. In this system, the seeds of each ear that had purple pigmentation in the endosperm and absence of pigmentation in the embryo were selected as haploid seeds. After identification of haploids, chromosomal duplication was carried out to obtain doubled haploid lines.

For chromosomal duplication, 50 seeds from each source population were separated, resulting in nine groups and a total of 800 plants (16 populations x 50 plants). Chromosomal duplication was carried out in January 2019, adopting the protocol of Couto et al. (2013CoutoEGDODavideLMCBustamanteFDOPinhoRGVSilvaTN2013 Identification of haploid maize by flow cytometry, morphological and molecular markers. Ciência e Agrotecnologia 37:25-31). The haploid seeds were sown in plastic trays containing vermiculite and kept in greenhouse at a temperature of 25 ºC and relative humidity of 60%. At 15 days after sowing, the seedlings went through the chromosomal duplication process in the doubled haploid technology laboratory of Embrapa Milho e Sorgo. Initially, the seedlings were carefully removed from the trays, and the roots were washed in running water. They were then grouped in bundles of 25 seedlings, identified according to their source population and each bundle was inserted in 800-mL beakers with water, to avoid wilting. For chromosomal duplication, a solution was prepared composed of the following reagents: 1% colchicine (w/v), 1% dimethyl sulfoxide (v/v), and 1% Tween 20 (v/v). After preparation, 185 mL of this solution was distributed in 600-mL beakers. These beakers were transferred to a fume hood, and 25 identified seedlings was inserted in each one. The seedlings were kept under treatment for six hours in the absence of light and at ambient temperature.

After six hours of treatment in the colchicine solution, the seedlings were removed from the solution and placed in cube-shaped screened containers, and then transferred to a tank for spray washing for 30 minutes. After that, the supposed doubled haploid seedlings were transplanted to plastic trays containing commercial substrate and transported to a greenhouse, where they were kept for 20 days for recovery from the colchicine treatment. The supposed doubled haploid seedlings were carefully removed from the trays with substrates and manually transplanted to 20-L pots with soil fertilized using a dose equivalent to 2000 kg ha^-1 of 4-28-16 (N-P-K) + Zn. Three seedlings were transplanted per pot and identified by treatment in February of 2019, and the pots were kept in a climate-controlled greenhouse. Management practices after planting were carried out according to crop requirements (Amaral Filho et al. 2005Amaral FilhoJPRDFornasieri FilhoDFarinelliRBarbosaJC2005 Row spacing, population density and nitrogen fertilization in maize. Revista Brasileira de Ciência do Solo 29:467-473).

For identification of DH through leaf anatomy, six genotypes were selected in the V6 stage (four DH and two FP plants) in each one of the nine groups and generations of source populations (Table 1). DH and FP were differentiated based on morpho-agronomic traits (plant height, leaf angle, and stem and leaf color). A sample from the fifth fully expanded leaf (counting from lower to higher) was collected from each plant, resulting in a total of 96 samples (6 plants x 16 populations), considering the nine groups of DH lines. To standardize collection of samples in the plants selected, on the fifth leaf of each plant, a measurement of 3 cm was made in the direction from the base to the tip. Starting at this point, a 1 cm rectangular sample of leaf was collected and cut in a direction transversal to the middle part of the leaf blade. These samples were placed in labeled tubes containing 70% ethanol. The tubes were then taken to totally remove chlorophyll from the leaf and obtain estimates of stomatal size and density. Removal was facilitated by four exchanges of 70% ethanol at intervals of 24 hours over three days.

To capture images of the stomata, a rectangular subsample was collected from the leaf sample after removal of chlorophyll, using a scalpel. After that, 70% alcohol was added to the glass slide, covering the sample with a cover slip. Microscopic analyses of the slides were carried out without the use of staining. The stomata were visualized using a stereoscopic electronic microscope, at maximum magnification (112 x), with an attached camera at the magnification of 112 x 0.459 mm. The lens was focused on the region near the midrib on the abaxial part of the leaf, and the image was transmitted to a computer for measurement. To obtain the size of the stomata, a fixed size scale of the equipment was added for assessment, measuring the height and width of the extremities of the guard cells of each stoma, with a total of 10 stomata/image, for each one of the six genotypes selected (four DH and two FP plants). After that, the area of each stoma was estimated through application of the formula:

= a . b . π

where a is the smaller radius and b is the larger radius. In the same area in which the stomata were measured, stomatal density was evaluated by manual count in a standard image area of 112 x 0.459 mm.

After self-pollination of the plants and harvest, preliminary selection of the DH sampled was confirmed by morpho-agronomic traits. Thus, ears with one or few seeds of yellow color confirm a DH plant, whereas ears with high grain formation and seeds with white color and/or the presence of anthocyanin indicate FP. This information was crossed with the data on stomatal density and area obtained in the evaluations for identification of putative DH and FP.

The statistical procedures

First of all, it is necessary to bear in mind that haploids were not obtained from all the generations (F₁, F₂, and F₃) due to loss of plants/generations, e.g. only population 7 had the three generations (see Table 1). This situation resulted in an unbalanced dataset. For this reason, it was decided to process the data by residual maximum likelihood (Patterson and Thompson 1971PattersonHDThompsonR1971 Recovery of interblock information when block sizes are unequal. Biometrika 58:545-554), a suitable method for dealing with unbalanced data. In addition, the generation factor was disregarded, assuming that all populations were in the same generation. In terms of breeding, the progenies of the crosses of the different groups of population, in different levels of inbreeding (generations), when pollinated exclusively by the inducing single hybrid TAIL P1 x TAIL P2, have inbreeding coefficients equal to zero, regardless of the plants used as mothers and their respective previous levels of inbreeding.

The statistical model used to determine the stomatal area and density data, considering a completely randomized design in a factorial scheme, was:

$y = μ + p_{i} + g_{j} + {p g}_{i j} + ε_{i j}$

where y is the phenotypic observation, μ is the intercept, p _i is the effect of the i-th population, g _j is the effect of the j-th genotype (DH or FP - false positive), pg _ij is the effect of the interaction of the i-th population with the j-th genotype and ε_ij is the residual effect. All model effects were considered fixed, with the exception of the residual.

The significance of the effects was verified using the Wald test (Wald 1945WaldA1945 Sequential tests of statistical hypotheses. The Annals of Mathematical Statistics 16:117-186) and the adjusted means for the fixed effects were obtained by the BLUE (Best Linear Unbiased Estimator) method (Henderson 1975HendersonCR1975 "Best linear unbiased estimation and prediction under a selection model". Biometrics 31:423-447). The decision on whether the adjusted means differed was based on confidence intervals, obtained by:

$L i m = B L U E \pm 1.96 * S E$

where Lim is the upper or lower limit and SE is the standard error of the BLUE estimate. All analyses were performed in the R software (R Core Team 2022R Core Team2021 R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna. Available at <https://www.R-project.org/>. Accessed on March 10, 2022.), using the ASReml-R package (Butler et al. 2018ButlerDGCullisBRGilmourARGogelBJThompsonR2018 ASReml-R reference manual Version 4. UK, VSN International, Hemel Hempstead.).

RESULTS AND DISCUSSION

For both stomatal area (µm²) and density (number of stomata per area of 112 x 0.459 mm) the Wald test value indicated significance for the effects of populations and genotypes (Table 2). The difference between genotypes (DH and FP) corroborated the possibility of using both stomatal area and density as differentiators between haploids and diploids (Choe et al. 2012ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401, Souza et al. 2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ). There was a highly significant effect of the interaction between genotypes (DH and FP) and populations on stomatal area. In other words, genotypes react differently depending on the source population from which they are obtained, when considering the stomatal area. On the other hand, this dependence was not verified for stomatal density (Table 2), indicating the potential of this trait to distinguish DH from FP.

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Table 2
Summary of the statistical analyses for stomatal area and density, evaluated in double haploid lines and false positives (Genotypes) from nine source populations

The experimental coefficients of variation (CV) were similar for both stomatal area and density (approximately 27%). These CV values were high for laboratory experiments where environmental conditions are controlled. Souza et al. (2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ) evaluated doubled haploid, haploid and diploid progenies, and found CV of 12.33% for the stomatal density and 10.41% for the guard cell length. However, these authors evaluated only two progenies for each type of genotype, whereas, in our experiment, nine progenies coming from different source populations were evaluated. This resulted in greater variability in the genotypes under assessment, with wide amplitude detected for stomatal area (596 to 1318 μm²) and stomatal density (29 to 69 stomata per area of 112 x 0.459 mm) (Table 2).

Stomatal density and stomatal area are traits arising from leaf anatomy. Several studies attest to the utility of leaf anatomy as a tool for assisting the selection of genotypes (DH and FP plants). Choe et al. (2012ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401) evaluated haploid, double haploid, false positive and diploid maize and found that the guard cell length from the fifth leaf allowed the separation between these four classes with greater precision. Souza et al. (2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ) concluded that measuring the traits of stomatal guard cell length and stomatal density would be an efficient and non-destructive methodology for selecting DH and FP plants. Stomatal density as a differentiating trait of haploids, compared to stomatal area and guard cell length, can be implemented using simple observation and counting under microscopes, adding greater ease of measurement.

Thus, the implementation of the leaf anatomy as a tool to assist in the selection of haploids and doubled haploids can increase efficiency in the production of DHs, allowing the differentiation of diploids (FP) from haploid and doubled haploids at an initial stage. Haploidy may be induced in any type of population and generation. In maize, the technology of DH lines has been used in obtaining lines from F₁ hybrids (Trindade et al. 2019TrindadeRSGuimaraesLJMSouzaIRPGuimaraesPEOSilvaACAMarizBRibeiroMR2019 Generations advance effects in haploid induction on maize donor populations. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/205880/1/bol-193.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ), selected according to the aims of the program. Depending on the genetic background of the germplasm used, mainly in tropical germplasm, identification in seeds can become difficult, due to the inhibition of the marker R1-nj. This fact makes a secondary trait, such as stomatal density, advantageous for differentiating haploids.

In terms of genotype, for the stomatal density, the Flint group seemed to exhibit greater variability (Figure 1A). For stomatal area the variability was greater for the Dent group (Figure 1B). The data obtained corroborate that the values of stomatal area and number of stomata are affected by the genotype (Table 2). However, the type of genotype can be a differentiation factor. In relation to stomatal density, DH lines were distinguished statistically from FP lines (Figure 2). On the other hand, stomatal area was more reduced in DH lines than in diploid individuals (FP) (Figure 2), denoting a compensatory effect, in which the smaller stomatal area is balanced by the greater density of the stomata per leaf (Figure 2).

Figure 1
BLUES of stomatal density (A) and area (B) (with bars showing the confidence interval) of nine source populations of Flint and Dent groups, considering DH (doubled haploid) and FP (false positive) genotypes.

Figure 2
BLUES of stomatal density (with bars showing the confidence interval) of DH (doubled haploid) and FP (false positive) genotypes.

The tendency to a larger number of stomata with smaller area in the DHs evaluated is also noteworthy, indicating an effect directly associated with photosynthetic processes (Melkonian et al. 2004MelkonianJYuLXSetterTL2004 Chilling responses of maize (Zea mays L.) seedlings: Root hydraulic conductance, abscisic acid, and stomatal conductance. Journal of Experimental Botany 55:1751-1760). This denotes that smaller stomatal area, which would hinder gas exchanges, is compensated by greater stomatal density. Souza et al. (2018SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf . Accessed on January 05, 2021.
https://ainfo.cnptia.embrapa.br/digital/... ) evaluated the types of genotypes (haploids, doubled haploids, and diploids) and found that the diploids, false positives, formed a distinct group from the haploids and doubled haploids. The same researchers emphasized that the diploids exhibited intermediate values for stomatal density.

Leaf anatomy has been the focus of studies for different species. Through this methodology it is possible to associate the size of stomatal guard cells and ploidy levels. A study with sweet peppers (Capsicum annuum L.) confirmed that the mean stomatal length was greater in diploids (35.2 ± 2.5 μm) and smaller in haploids (26.4 ± 2.4 μm) (Shrestha and Kang 2016ShresthaSLKangWH2016 Stomata length and density as an indicator of ploidy level in sweet pepper (Capsicum annuum L.). Research Journal of Recent Sciences 5:4-10). Przywara et al. (1988PrzywaraLPandeyKKSandersPM1988 Length of stomata as an indicator of ploidy level in Actinidia deliciosa. New Zealand Journal of Botany 26:179-182) studied kiwi (Actinidia deliciosa) and found correlation between the length of the stomatal guard cells and distinction of haploid and diploid plants (24 ± 1.7 μm and 33 ± 2.4 μm, respectively). Choe et al. (2012ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401) found that the mean length of the stomatal guard cells is an efficient trait for differentiation of haploid and diploid plants in maize. Sekiya et al. (2020SekiyaAPestanaJKSilvaMGBKrauseMDSilvaCRMFerreiraJM2020 Haploid induction in tropical supersweet corn and ploidy determination at the seedling stage. Pesquisa Agropecuária Brasileira 55:e00968) evaluated samples of maize leaves collected in the V2/V3 stages and found that the morphometry of the stomata is an efficient methodology for distinction between haploids and false positives in sweet corn. Thus, our study confirms the efficiency of evaluation of stomatal density for distinction of DH and FP and for selection of DH.

FINAL CONSIDERATIONS

For the set of DH evaluated, stomatal area showed variation as a function of the source population, genotype and the interaction between both factors, making it difficult to use it as a trait to distinguish between DH and FP.

In turn, stomatal density varied as a function of source population and genotype, but showed no interaction between these factors, which could serve as a differentiating trait between DH and FP.

ACKNOWLEDGMENTS

The authors are grateful to Embrapa Maize and Sorghum, Minas Gerais State Research Support Foundation (FAPEMIG), National Council for Scientific and Technological Development (CNPq) and Brazilian Coordination for the Improvement of Higher Education Personnel (CAPES) for the financial support, as well as to Prof. Denise Dias, Prof. Maicon Nardino, Dr. Paulo Evaristo and Dr. Meire Alves for their assistance in data discussing. The authors are also grateful for the criticisms and suggestions of the anonymous reviewers who greatly contributed to the improvement of the paper.

REFERENCES

Amaral FilhoJPRDFornasieri FilhoDFarinelliRBarbosaJC2005 Row spacing, population density and nitrogen fertilization in maize. Revista Brasileira de Ciência do Solo 29:467-473
ButlerDGCullisBRGilmourARGogelBJThompsonR2018 ASReml-R reference manual Version 4. UK, VSN International, Hemel Hempstead.
ChaikamVMolenaarWMelchingerAEBoddupalliPM2019 Doubled haploid technology for line development in maize: Technical advances and prospects. Theoretical and Applied Genetics 132:3227-3243
ChaikamVLopezLAMartinezLBurgueñoJBoddupalliPM2017 Identification of in vivo induced maternal haploids in maize using seedling traits. Euphytica 213:1-9
ChaikamVMartinezLMelchingerAESchipprackWBoddupalliPM2016 Development and validation of red root marker-based haploid inducers in maize. Crop Science 56:1678-168
ChaikamVNairSKBabuRMartinezLTejomurtulaJBoddupalliPM2015 Analysis of effectiveness of R1-nj anthocyanin marker for in vivo haploid identification in maize and molecular markers for predicting the inhibition of R1-nj expression. Theoretical and Applied Genetics 128:159-171
ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401
CoutoEGDODavideLMCBustamanteFDOPinhoRGVSilvaTN2013 Identification of haploid maize by flow cytometry, morphological and molecular markers. Ciência e Agrotecnologia 37:25-31
FAO - Food and Agriculture Organization of the United Nations2020 Statistical yearbook 2020. Rome. https://doi.org/10.4060/cb1329en. Available at: <Available at: http://www.fao.org/3/cb1329en/CB1329EN.pdf >. Accessed on January 05, 2021.
» http://www.fao.org/3/cb1329en/CB1329EN.pdf
HanYGuYZhangACLoYH2016 Imaging technologies for flow cytometry. Lab on a Chip 16:4639-4647
HendersonCR1975 "Best linear unbiased estimation and prediction under a selection model". Biometrics 31:423-447
LiuZWangYRenJMeiMFreiUKTrampeBLübberstedtTOrtizR2016 Maize doubled haploids. Plant Breed Review 40:123-166
MelchingerAESchipprackWFriedrich UtzHMirditaV2014 In vivo haploid induction in maize: identification of haploid seeds by their oil content. Crop Science 54:1497-1504
MelkonianJYuLXSetterTL2004 Chilling responses of maize (Zea mays L.) seedlings: Root hydraulic conductance, abscisic acid, and stomatal conductance. Journal of Experimental Botany 55:1751-1760
NandaDKChaseSS1966 An embryo marker for detecting monoploids of maize (Zea Mays L.) 1. Crop Science 6:213-215
PattersonHDThompsonR1971 Recovery of interblock information when block sizes are unequal. Biometrika 58:545-554
PierrePMODavideLMCCoutoEGOSilvaTNRamalhoMAPSantosJB2011 Duplo-haploides: estratégias para obtenção e importância no melhoramento genético do milho. Revista Brasileira de Milho e Sorgo 10:1-16
PrasannaBM2012 Doubled haploid technology in maize breeding: An overview. In Prasanna BM, Chaikam V and Mahuku G (eds) Doubled haploid technology in maize breeding: Theory and practice. CIMMYT, Mexico, p. 1-8
PrzywaraLPandeyKKSandersPM1988 Length of stomata as an indicator of ploidy level in Actinidia deliciosa. New Zealand Journal of Botany 26:179-182
R Core Team2021 R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna. Available at <https://www.R-project.org/>. Accessed on March 10, 2022.
RibeiroCBPereiraFDCNóbrega FilhoLDRezendeBADiasKODGBrazGTRuyMCSilvaMBCenziGTechioVHSouzaJCD2018 Haploid identification using tropicalized haploid inducer progenies in maize. Crop Breeding and Applied Biotechnology 18:16-23
SmelserABlancoMLübberstedtLübberstedtTTSchechertAVanousAGardnerC2015 Weighing in on a method to discriminate maize haploid from hybrid seed. Plant Breeding 134:283-285
ShresthaSLKangWH2016 Stomata length and density as an indicator of ploidy level in sweet pepper (Capsicum annuum L.). Research Journal of Recent Sciences 5:4-10
SekiyaAPestanaJKSilvaMGBKrauseMDSilvaCRMFerreiraJM2020 Haploid induction in tropical supersweet corn and ploidy determination at the seedling stage. Pesquisa Agropecuária Brasileira 55:e00968
SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf Accessed on January 05, 2021.
» https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf
TrindadeRSGuimaraesLJMSouzaIRPGuimaraesPEOSilvaACAMarizBRibeiroMR2019 Generations advance effects in haploid induction on maize donor populations. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/205880/1/bol-193.pdf Accessed on January 05, 2021.
» https://ainfo.cnptia.embrapa.br/digital/bitstream/item/205880/1/bol-193.pdf
USDA - United States Department of Agriculture2022 World agricultural production. Circular series WAP 3-22
XuYLiPZouCLuYXieCZhangXPrasannaMBOlsenMS2017 Enhancing genetic gain in the era of molecular breeding. Journal of Experimental Botany 68:2641-2666
WaldA1945 Sequential tests of statistical hypotheses. The Annals of Mathematical Statistics 16:117-186
WangHDongBJiangJFangWGuanZLiaoYChenSChenF2014 Characterization of in vitro haploid and doubled haploid Chrysanthemum morifolium plants via unfertilized ovule culture for phenotypical traits and DNA methylation pattern. Frontiers in Plant Science 5:738
WuPRenJLiLChenS2014 Early spontaneous diploidization of maternal maize haploids generated by in vivo haploid induction. Euphytica 200:127-138
ZhangWWangKLinZSDuLPMaHLXiaoLLYeXG2014 Production and identification of haploid dwarf male sterile wheat plants induced by corn inducer. Botanical Studies 55:1-8

Publication Dates

Publication in this collection
01 July 2022
Date of issue
2022

History

Received
11 July 2021
Accepted
06 May 2022
Accepted
31 May 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Amaral FilhoJPRDFornasieri FilhoDFarinelliRBarbosaJC2005 Row spacing, population density and nitrogen fertilization in maize. Revista Brasileira de Ciência do Solo 29:467-473

[2] ButlerDGCullisBRGilmourARGogelBJThompsonR2018 ASReml-R reference manual Version 4. UK, VSN International, Hemel Hempstead.

[3] ChaikamVMolenaarWMelchingerAEBoddupalliPM2019 Doubled haploid technology for line development in maize: Technical advances and prospects. Theoretical and Applied Genetics 132:3227-3243

[4] ChaikamVLopezLAMartinezLBurgueñoJBoddupalliPM2017 Identification of in vivo induced maternal haploids in maize using seedling traits. Euphytica 213:1-9

[5] ChaikamVMartinezLMelchingerAESchipprackWBoddupalliPM2016 Development and validation of red root marker-based haploid inducers in maize. Crop Science 56:1678-168

[6] ChaikamVNairSKBabuRMartinezLTejomurtulaJBoddupalliPM2015 Analysis of effectiveness of R1-nj anthocyanin marker for in vivo haploid identification in maize and molecular markers for predicting the inhibition of R1-nj expression. Theoretical and Applied Genetics 128:159-171

[7] ChoeECarboneroCHMulvaneyKRayburnALMummRH2012 Improving in vivo maize doubled haploid production efficiency through early detection of false positives. Plant Breeding 131:399-401

[8] CoutoEGDODavideLMCBustamanteFDOPinhoRGVSilvaTN2013 Identification of haploid maize by flow cytometry, morphological and molecular markers. Ciência e Agrotecnologia 37:25-31

[9] FAO - Food and Agriculture Organization of the United Nations2020 Statistical yearbook 2020. Rome. https://doi.org/10.4060/cb1329en. Available at: <Available at: http://www.fao.org/3/cb1329en/CB1329EN.pdf >. Accessed on January 05, 2021.
» http://www.fao.org/3/cb1329en/CB1329EN.pdf

[10] HanYGuYZhangACLoYH2016 Imaging technologies for flow cytometry. Lab on a Chip 16:4639-4647

[11] HendersonCR1975 "Best linear unbiased estimation and prediction under a selection model". Biometrics 31:423-447

[12] LiuZWangYRenJMeiMFreiUKTrampeBLübberstedtTOrtizR2016 Maize doubled haploids. Plant Breed Review 40:123-166

[13] MelchingerAESchipprackWFriedrich UtzHMirditaV2014 In vivo haploid induction in maize: identification of haploid seeds by their oil content. Crop Science 54:1497-1504

[14] MelkonianJYuLXSetterTL2004 Chilling responses of maize (Zea mays L.) seedlings: Root hydraulic conductance, abscisic acid, and stomatal conductance. Journal of Experimental Botany 55:1751-1760

[15] NandaDKChaseSS1966 An embryo marker for detecting monoploids of maize (Zea Mays L.) 1. Crop Science 6:213-215

[16] PattersonHDThompsonR1971 Recovery of interblock information when block sizes are unequal. Biometrika 58:545-554

[17] PierrePMODavideLMCCoutoEGOSilvaTNRamalhoMAPSantosJB2011 Duplo-haploides: estratégias para obtenção e importância no melhoramento genético do milho. Revista Brasileira de Milho e Sorgo 10:1-16

[18] PrasannaBM2012 Doubled haploid technology in maize breeding: An overview. In Prasanna BM, Chaikam V and Mahuku G (eds) Doubled haploid technology in maize breeding: Theory and practice. CIMMYT, Mexico, p. 1-8

[19] PrzywaraLPandeyKKSandersPM1988 Length of stomata as an indicator of ploidy level in Actinidia deliciosa. New Zealand Journal of Botany 26:179-182

[20] R Core Team2021 R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna. Available at <https://www.R-project.org/>. Accessed on March 10, 2022.

[21] RibeiroCBPereiraFDCNóbrega FilhoLDRezendeBADiasKODGBrazGTRuyMCSilvaMBCenziGTechioVHSouzaJCD2018 Haploid identification using tropicalized haploid inducer progenies in maize. Crop Breeding and Applied Biotechnology 18:16-23

[22] SmelserABlancoMLübberstedtLübberstedtTTSchechertAVanousAGardnerC2015 Weighing in on a method to discriminate maize haploid from hybrid seed. Plant Breeding 134:283-285

[23] ShresthaSLKangWH2016 Stomata length and density as an indicator of ploidy level in sweet pepper (Capsicum annuum L.). Research Journal of Recent Sciences 5:4-10

[24] SekiyaAPestanaJKSilvaMGBKrauseMDSilvaCRMFerreiraJM2020 Haploid induction in tropical supersweet corn and ploidy determination at the seedling stage. Pesquisa Agropecuária Brasileira 55:e00968

[25] SouzaIRPTrindadeRSVasconcelosMJVPaulaALSPVGuimarãesPEOGuimarãesLJMAlvesMC2018 Strategies for identification of false positives in the production of double-haploides in maize. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf Accessed on January 05, 2021.
» https://ainfo.cnptia.embrapa.br/digital/bitstream/item/193323/1/bol-171.pdf

[26] TrindadeRSGuimaraesLJMSouzaIRPGuimaraesPEOSilvaACAMarizBRibeiroMR2019 Generations advance effects in haploid induction on maize donor populations. Avaiable at: Avaiable at: https://ainfo.cnptia.embrapa.br/digital/bitstream/item/205880/1/bol-193.pdf Accessed on January 05, 2021.
» https://ainfo.cnptia.embrapa.br/digital/bitstream/item/205880/1/bol-193.pdf

[27] USDA - United States Department of Agriculture2022 World agricultural production. Circular series WAP 3-22

[28] XuYLiPZouCLuYXieCZhangXPrasannaMBOlsenMS2017 Enhancing genetic gain in the era of molecular breeding. Journal of Experimental Botany 68:2641-2666

[29] WaldA1945 Sequential tests of statistical hypotheses. The Annals of Mathematical Statistics 16:117-186

[30] WangHDongBJiangJFangWGuanZLiaoYChenSChenF2014 Characterization of in vitro haploid and doubled haploid Chrysanthemum morifolium plants via unfertilized ovule culture for phenotypical traits and DNA methylation pattern. Frontiers in Plant Science 5:738

[31] WuPRenJLiLChenS2014 Early spontaneous diploidization of maternal maize haploids generated by in vivo haploid induction. Euphytica 200:127-138

[32] ZhangWWangKLinZSDuLPMaHLXiaoLLYeXG2014 Production and identification of haploid dwarf male sterile wheat plants induced by corn inducer. Botanical Studies 55:1-8

		Stomatal area (μm²)			Stomatal density (stomata per area of 112 x 0.459 mm)
Sources of variation	df	Wald test value		df	Wald test value
Population (P)	8	66.50	**	8	31.97	**
Genotype (G)	1	97.40	**	1	22.53	**
P x G	8	174.6	**	8	13.27
Error	692			73
Mean		821.45			46.12
Minimum		596.08			28.75
Maximum		1317.78			69.25
CV (%)		26.74			27.04

Nr. of source populations (P)	Generations	Heterotic groups
1	F₁, F₃	Flint
2	F₃	Flint
3	F₂, F₃	Flint
4	F₂, F₃	Flint
5	F₁, F₂	Flint
6	F₁	Dent
7	F₁, F₂, F₃	Dent
8	F₁, F₃	Dent
9	F₃	Dent