‘UENF 506-11’: a new maize cultivar for the North and Northwest of Rio de Janeiro State

Pereira, Messias Gonzaga; Berilli, Ana Paula Candido Gabriel; Trindade, Roberto dos Santos; Entringer, Geovana Cremonini; Santos, Pedro Henrique Araújo Diniz; Vettorazzi, Julio Cesar Fiorio; Galvão, Keila Silva da Cunha

doi:10.1590/1984-70332019v19n1c20

Abstract

The intervarietal hybrid ‘UENF 506-11’ was derived from full-sib maize families in the 11^th cycle of reciprocal recurrent selection. It produces a grain yield of 7.57 tons ha^-1, and is recommended for cultivation in the North and Northwest regions of the Rio de Janeiro State.

Keywords:
Zea mays L.; reciprocal recurrent selection; cultivar; plant breeding.

INTRODUCTION

Maize (Zea mays L.) is a cereal of great economic and social importance, cultivated in almost all agricultural regions of the world and used in human and animal nutrition and, more recently, as a source of biofuel. Brazil is the third largest producer in the world, with a production in the year 2017 of 97 million tons, which is surpassed only by the United States and China (FAOSTAT, 2019FAOSTAT (2019) Food and Agriculture organization of the United Nations. Production quantities of Maize by country 2017. Available at: <Available at: http://www.fao.org/faostat/en/#data/QC/visualize >. Access in Marh, 2019.
http://www.fao.org/faostat/en/#data/QC/v... ). Much of the yield potential of this crop in the country is the result of significant advances in breeding programs, which have progressively improved agronomic traits related to grain yield, disease resistance and adaptability to adverse conditions.

For the state of Rio de Janeiro, no agricultural zoning indicates which cultivars are best planted. Maize is grown almost exclusively by small farmers with low technological input, generally without irrigation, for grain and silage production. Mostly, the farmers grow open-pollinated varieties and hybrids developed for other regions of Brazil.

Historically, until the 1980s, the North and Northwest of Rio de Janeiro stood out as one of the largest sugarcane-producing regions of Brazil (Silva 2006Silva LC (2006) Reconfiguração do Norte Fluminense a partir dos anos 70: a chegada do petróleo e suas consequências na dinâmica de crescimento regional. Revista Plurais 1: 167-187. ). However, dwindling yields caused by a decline in natural soil fertility due to successive cultivation without nutrient replenishment and increased production costs, led to a decline in sugarcane farming in the region (Castro and Ribeiro 2010Castro RAR and Ribeiro AC (2010) Relações de cooperação no aglomerado sucroalcooleiro fluminense: reflexões sobre o papel do recurso intangível no desenvolvimento regional. Agenda Social 4: 59-75.). In this context, considering the edaphoclimatic conditions of the North and Northwest of Rio de Janeiro, with an undulating plain relief, appropriate for a mechanized crop management, and for maize cultivation destined for grain as well as silage for livestock, the potential of maize is perceived as an important alternative of crop diversification for the region.

In 1996, the Universidade Estadual do Norte Fluminense Darcy Ribeiro (UENF) initiated a maize breeding program based on Full-sib Reciprocal Recurrent Selection (FSRRS). The continuous progress of this breeding program has provided maize producers in the North and Northwest regions of Rio de Janeiro with hybrids with excellent agronomic response and adapted to the regional conditions. In 2000, this program released the inter-populational hybrid 'UENF 506-6' with superior agronomic performance over other cultivars, which has been successfully used by farmers (Tardin et al. 2007Tardin FD, Pereira MG, Gabriel APC, Amaral Junior AT and Filho GAS (2007) Selection index and molecular markers in reciprocal recurrent selection in maize. Crop Breeding and Applied Biotechnology 7: 225-233., Berilli et al. 2013Berilli APCG, Pereira MG, Trindade RS and Costa FR (2013) Response to the selection in the 11th cycle of reciprocal recurrent selection among full-sib families of maize. Acta Scientiarum 35: 435-441.).

The objective of this study was to describe the main traits of the intervarietal maize hybrid 'UENF 506-11', of the 11^th cycle of FSRRS.

PEDIGREE AND BREEDING METHOD

Two maize populations of different heterotic groups were used, one called CIMMYT and the other Piranão, of the heterotic groups "flint" and “dent”, respectively. Both populations have the brachytic gene (br ₂ ), introduced by backcrossing in a pre-breeding stage, resulting in short plant height. Both populations came from the Universidade Federal de Viçosa (UFV), where they undergone five cycles of FSRRS. As of the sixth cycle, selection was carried out at the UENF.

The FSRRS was described by Hallauer and Eberhart (1970Hallauer AR and Eberhart SA (1970) Reciprocal full-sib selection. Crop Science 10: 315-316. ). This methodology promotes the accumulation of favorable alleles within the involved populations and increases the combining ability among them, preserving the genetic variability among and within them (Reis et al. 2009Reis MC, Souza JC, Ramalho MAP, Guedes FL and Santos PHAD (2009) Progresso genético com a seleção recorrente recíproca para híbridos interpopulacionais de milho. Pesquisa Agropecuária Brasileira 44: 1667-1672.).

FIELD TRIALS

Field evaluations were performed from September to February in the growing seasons of 2009/2010, 2010/2011 and 2011/2012 at three locations: two in Campos dos Goytacazes - RJ and one in Itaocara - RJ, totaling nine environments. These nine constitute the environments where the VCU (Value for Cultivation and Use) trials were carried out. In all trials, a randomized complete block design with five replications was used. The experimental plots consisted of a single 4.0 m row, at a plant spacing of 0.2 m between plants and 1.0 m between rows.

Twenty-one genotypes of the FSRRS program of the UENF, seven of which were intervarietal hybrids between the CIMMYT and Piranão populations and the respective parent populations, were evaluated. In addition, seven control genotypes were evaluated: two commercial hybrids ('AG 1051' and 'BM 2202'), an intervarietal hybrid ('Fortaleza' versus CIMMYT 8), three commercial varieties ('BR 106', 'Fortaleza' and 'Sol da Manhã'), and the Composto Caboclo br ₂ . For the sake of simplicity, only the results of the registered intervarietal hybrid (‘UENF 506-11’) and the controls used in the experiment were presented (Table 1).

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Table 1
Summary of analysis of variance with the respective mean squares, coefficients of experimental variation (CV), means of the evaluated traits and coefficient of genotypic determination (H²), between 2009 and 2012 in three environments.

The crop management at the different locations and in all trials was applied as recommended for maize (Fancelli and Dourado Neto 2000Fancelli AL and Dourado Neto D (2000) Produção de milho. Agropecuária, Guaíba, 360p.). During the experimental period, seven maize descriptors and nine morpho-agronomic traits were evaluated, according to the minimum requirements for registry in the national cultivar registration system (MAPA 2019MAPA - Ministério da Agricultura, Pecuária e Abastecimento (2019). Valor de cultivo e uso. Available at: < Available at: http://sistemas.agricultura.gov.br/snpc/cultivarweb/index.php >. Access in March, 2019.
http://sistemas.agricultura.gov.br/snpc/... ). The plots were harvested by hand and the grain yield was weighed considering a grain moisture content of 13%.

STATISTICAL ANALYSES

An individual ANOVA of the morpho-agronomic traits was performed for each environment (data not shown). The coefficients of variation for all environments were found to be lower than 20%, so the homogeneity of the residual variances was evaluated by the F test (Hartley 1950Hartley HO (1950) The maximum F-ratio as a short-cut teste for heterogeneity of variances. Biometrika 37: 308-312.). The combined analysis of experiments was performed since the ratio between the highest and the lowest residual F for the evaluated environments was less than seven (Table 1). Tukey mean test at 5% probability was applied based on the mean of the tested environments. Software GENES (Cruz 2013Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum Agronomy 35: 271-276.) was used for all statistical analyses. For the genotype x environment interaction for the trait grain yield, significance at 5% probability was observed, but since these environments were close together and in view of the excellent performance of hybrid ‘UENF 506-11’ in the different environments, there was no need to register different hybrids for these regions. Thus, the overall means were considered for the mean test comparisons.

AGRONOMIC PERFORMANCE

In three growing seasons at three locations the grain yield of the inter-population hybrid 'UENF 506-11' was only surpassed by hybrid 'AG1051' (Table 2). The Tukey mean test indicated that the intervarietal hybrid ‘UENF 506-11’ had a similar grain yield to the commercial hybrid ‘BM 2202’ and higher than that of the commercial varieties ‘BR 106’ and ‘Sol da Manhã’, and was only lower than that of the commercial hybrid ‘AG 1051’.

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Table 2
Yield of ‘UENF 506-11’ compared to the mean of four controls by Tukey test (P>0.05) in evaluations between 2009 and 2012 in three environments

OTHER TRAITS

The main traits of hybrid 'UENF 506-11' were compared to the other cultivars used in the region and evaluated in the experiment (Table 3). Hybrid 'UENF 506-11' is appropriate for grain or silage production or for fresh consumption. The grain is classified as semi-hard and yellow/orange. The recommended cultivation period for the intervarietal hybrid is between September and February.

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Table 3
Descriptive statistics for eight agronomic traits of three maize genotypes evaluated in tests of value for cultivation and use (VCU), in the growing seasons of 2009, 2010 and 2012, at three locations

SEED PRODUCTION AND DISTRIBUTION

The intervarietal hybrid ‘UENF 506-11’ was registered by the Ministry of Agriculture, Livestock and Supply - MAPA (no. 30595). Seeds are produced and commercialized by Rio Norte Sementes Company in partnership with UENF.

REFERENCES

Berilli APCG, Pereira MG, Trindade RS and Costa FR (2013) Response to the selection in the 11^th cycle of reciprocal recurrent selection among full-sib families of maize. Acta Scientiarum 35: 435-441.
Castro RAR and Ribeiro AC (2010) Relações de cooperação no aglomerado sucroalcooleiro fluminense: reflexões sobre o papel do recurso intangível no desenvolvimento regional. Agenda Social 4: 59-75.
Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum Agronomy 35: 271-276.
Fancelli AL and Dourado Neto D (2000) Produção de milho. Agropecuária, Guaíba, 360p.
FAOSTAT (2019) Food and Agriculture organization of the United Nations. Production quantities of Maize by country 2017. Available at: <Available at: http://www.fao.org/faostat/en/#data/QC/visualize >. Access in Marh, 2019.
» http://www.fao.org/faostat/en/#data/QC/visualize
Hallauer AR and Eberhart SA (1970) Reciprocal full-sib selection. Crop Science 10: 315-316.
Hartley HO (1950) The maximum F-ratio as a short-cut teste for heterogeneity of variances. Biometrika 37: 308-312.
MAPA - Ministério da Agricultura, Pecuária e Abastecimento (2019). Valor de cultivo e uso. Available at: < Available at: http://sistemas.agricultura.gov.br/snpc/cultivarweb/index.php >. Access in March, 2019.
» http://sistemas.agricultura.gov.br/snpc/cultivarweb/index.php
Reis MC, Souza JC, Ramalho MAP, Guedes FL and Santos PHAD (2009) Progresso genético com a seleção recorrente recíproca para híbridos interpopulacionais de milho. Pesquisa Agropecuária Brasileira 44: 1667-1672.
Silva LC (2006) Reconfiguração do Norte Fluminense a partir dos anos 70: a chegada do petróleo e suas consequências na dinâmica de crescimento regional. Revista Plurais 1: 167-187.
Tardin FD, Pereira MG, Gabriel APC, Amaral Junior AT and Filho GAS (2007) Selection index and molecular markers in reciprocal recurrent selection in maize. Crop Breeding and Applied Biotechnology 7: 225-233.

Publication Dates

Publication in this collection
11 Apr 2019
Date of issue
Jan-Mar 2019

History

Received
02 Oct 2017
Accepted
05 Nov 2018

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

[1] Berilli APCG, Pereira MG, Trindade RS and Costa FR (2013) Response to the selection in the 11^th cycle of reciprocal recurrent selection among full-sib families of maize. Acta Scientiarum 35: 435-441.

[2] Castro RAR and Ribeiro AC (2010) Relações de cooperação no aglomerado sucroalcooleiro fluminense: reflexões sobre o papel do recurso intangível no desenvolvimento regional. Agenda Social 4: 59-75.

[3] Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum Agronomy 35: 271-276.

[4] Fancelli AL and Dourado Neto D (2000) Produção de milho. Agropecuária, Guaíba, 360p.

[5] FAOSTAT (2019) Food and Agriculture organization of the United Nations. Production quantities of Maize by country 2017. Available at: <Available at: http://www.fao.org/faostat/en/#data/QC/visualize >. Access in Marh, 2019.
» http://www.fao.org/faostat/en/#data/QC/visualize

[6] Hallauer AR and Eberhart SA (1970) Reciprocal full-sib selection. Crop Science 10: 315-316.

[7] Hartley HO (1950) The maximum F-ratio as a short-cut teste for heterogeneity of variances. Biometrika 37: 308-312.

[8] MAPA - Ministério da Agricultura, Pecuária e Abastecimento (2019). Valor de cultivo e uso. Available at: < Available at: http://sistemas.agricultura.gov.br/snpc/cultivarweb/index.php >. Access in March, 2019.
» http://sistemas.agricultura.gov.br/snpc/cultivarweb/index.php

[9] Reis MC, Souza JC, Ramalho MAP, Guedes FL and Santos PHAD (2009) Progresso genético com a seleção recorrente recíproca para híbridos interpopulacionais de milho. Pesquisa Agropecuária Brasileira 44: 1667-1672.

[10] Silva LC (2006) Reconfiguração do Norte Fluminense a partir dos anos 70: a chegada do petróleo e suas consequências na dinâmica de crescimento regional. Revista Plurais 1: 167-187.

[11] Tardin FD, Pereira MG, Gabriel APC, Amaral Junior AT and Filho GAS (2007) Selection index and molecular markers in reciprocal recurrent selection in maize. Crop Breeding and Applied Biotechnology 7: 225-233.

SV	DF	Mean squares
SV	DF	STAND	NLP	DFL	NE	EW	GW	HW	W100	GY
B/E	36	7.33	5.89	5.39	27.93	0.88	0.64	825.97	664.53	3.21
Block (B)	4	12.5	8.18	13.79	44.14	0.90	1.20	1213.34	320.78	5.99
B X E	32	6.68	5.6	4.34	25.91	0.88	0.57	777.55	707.50	2.86
Genotype (G)	4	285.19**	113.49**	155.44**	576.64**	36.5**	33.14**	29211.8**	12463.20**	163.74**
Environment (E)	8	97.47**	76.90**	424.55**	220.75**	13.26**	9.98**	5252.86**	11634.98**	49.34**
G X E	17	85.92**	12.16	13.02	127.56**	1.89	0.83*	2063.12	1616.72**	4.11*
Error	71	14.10	8.8	8.03	39.34	1.29	0.47	1378.66	556.26	2.35
Mean		23.23	2.4	62.99	25.27	3.61	3.02	744.29	304.34	6.72
CV (%)		16.16	123.59	4.49	24.81	31.43	22.77	4.9	7.75	22.78
H²		0.95	0.92	0.95	0.93	0.96	0.98	0.95	0.95	0.98

Cultivars	Grain yield (tons ha^-1)
AG 1051	8.86 a
‘UENF 506-11’	7.57 b
BM 2202	7.23 b
BR 106	6.14 c
SOL DA MANHÃ	3.78 d
MSD	0.69

		Morpho-agronomics traits
		Plant height	Ear height	Plant density	Ear index
‘UENF 506-11’	Mean	2.07	1.27	24	1.2
	Upper limit	2.63	2.25	30	1.6
	Lower limit	1.44	0.80	17	0.4
		Female flowering	Male flowering	1000-grain weight (g)	Grain yield (t ha^-1)
	Mean	64	64	314	7.57
	Upper limit	71	75	380	11.56
	Lower limit	59	58	250	1.78
		Plant height	Ear height	Plant density	Ear index
‘BM 2202’	Mean	1.85	0.99	25	1.1
	Upper limit	2.31	1.33	41	1.5
	Lower limit	1.41	0.54	18	0.5
		Female flowering	Male flowering	1000-grain weight (g)	Grain yield (t ha^-1)
	Mean	59	60	296	7.24
	Upperlimit	66	67	380	11.78
	Lower limit	53	54	210	0.57
		Plant height	Ear height	Plant density	Ear index
‘BR 106’	Mean	1.94	1.07	24	1.1
	Upper limit	2.38	1.80	29	1.8
	Lower limit	1.25	0.65	20	0.3
		Female flowering	Male flowering	1000-grain weight (g)	Grain yield (t ha^-1)
	Mean	59	61	304	6.15
	Upper limit	62	65	360	11.56
	Lower limit	53	54	248	1.08