Respostas fenológicas de cultivares brasileiras de trigo à vernalização e ao fotoperíodo

O objetivo deste trabalho foi avaliar o efeito de diferentes combinações de vernalização e fotoperíodo no desenvolvimento de cinco cultivares brasileiras de trigo. O experimento foi realizado em Passo Fundo, RS, em três épocas de semeadura: 23/6, 25/7 e 27/8 de 2003. O delineamento experimental foi o de blocos ao acaso com parcelas subsubdivididas e quatro repetições. Os tratamentos consistiram de: três regimes fotoperiódicos - fotoperíodo natural (FN), fotoperíodo estendido em quatro horas (FE 4) e fotoperíodo estendido até completar vinte horas de luz (FE 20) - locados na parcela principal; dois regimes de vernalização - não vernalizado (NV) e vernalizado com 30 dias (V) -, na subparcela; e cinco cultivares de trigo - BRS 179, BRS 194, BRS 207, BRS Figueira e BRS Umbu, avaliadas nas subsubparcelas. Houve interação entre fotoperíodo e cultivar (semeadura em 23/6), e todas as cultivares tiveram o ciclo reduzido com o aumento do fotoperíodo, enquanto nas plantas com épocas de semeadura 25/7 e 27/8, houve interação entre fotoperíodo e cultivar e entre vernalização e cultivar. Essas variáveis aceleraram o ciclo de desenvolvimento da cultura e interferiram na duração dos subperíodos importantes para a formação dos componentes do rendimento de grãos

Harnessing landrace diversity empowers wheat breeding

Harnessing genetic diversity in major staple crops through the development of new breeding capabilities is essential to ensure food security1. Here we examined the genetic and phenotypic diversity of the A. E. Watkins landrace collection2 of bread wheat (Triticum aestivum), a major global cereal, by whole-genome re-sequencing of 827 Watkins landraces and 208 modern cultivars and in-depth field evaluation spanning a decade. We found that modern cultivars are derived from two of the seven ancestral groups of wheat and maintain very long-range haplotype integrity. The remaining five groups represent untapped genetic sources, providing access to landrace-specific alleles and haplotypes for breeding. Linkage disequilibrium-based haplotypes and association genetics analyses link Watkins genomes to the thousands of identified high-resolution quantitative trait loci and significant marker–trait associations. Using these structured germplasm, genotyping and informatics resources, we revealed many Watkins-unique beneficial haplotypes that can confer superior traits in modern wheat. Furthermore, we assessed the phenotypic effects of 44,338 Watkins-unique haplotypes, introgressed from 143 prioritized quantitative trait loci in the context of modern cultivars, bridging the gap between landrace diversity and current breeding. This study establishes a framework for systematically utilizing genetic diversity in crop improvement to achieve sustainable food security

Physiological traits for improving wheat yield under a wide range of conditions

A better understanding of relatively simple crop-physiological attributes that determine yield in a wide range of conditions may be instrumental for assisting future breeding. Physiological traits may be selected either directly or through the use of molecular-biology tools. Physiological and breeding literature frequently distinguishes between yield under potential, stress-free conditions and under the pressure of stress, mostly abiotic. Although the rationale behind the idea that the different physiological attributes contribute to yield under these contrasting conditions may be sound, in practice there is a large body of evidence pointing out the other way around. For instance, genotypes with physiological attributes conferring higher yield potential usually also perform better under stress conditions, at least when excluding extremely severe environments. As breeders normally need to release improved cultivars to be grown in different sites throughout several seasons and subjected to a wide range of management decisions, identifying physiological traits that may confer simultaneously high yield potential and constitutive tolerance to stress would be critical. These traits must allow the plants to capture more resources or to use them more efficiently. A well-known attribute conferring high yield potential and widely studied physiologically has been semi-dwarfism. Semi-dwarf cultivars normally yield better than tall ones in a wide range of stressful conditions (at least if seedling emergence is not a major inconvenience). This is because reducing height to a certain level does not alter the ability of the crop to capture resources, whilst improving markedly the efficiency with which the resources are used to produce yield. This trait is not further useful as modern cultivars possess already a stature within the ranges optimizing yield. Two other traits that may also be associated with improved performance in a wide range of conditions may be the discrimination against 13C (?13C) and a lengthened stem elongation phase at the expense of previous phases. Although more research is needed before conclusions may be robust, physiological evidence supports the hypothesis that increasing ?13C and lengthening the stem elongation phase would result in an improved performance over a range of environmental condition

Comparative response of wheat and oilseed rape to nitrogen supply: absorption and utilisation efficiency of radiation and nitrogen during the reproductive stages determining yield

We investigated the response of spring wheat and oilseed rape to nitrogen (N) supply, focusing on the critical period for grain number definition and grain filling. Crops were grown in containers under a shelter and treated with five combinations of applied N. Wheat and oilseed rape produced comparable amounts of biomass and yield when corrected for the costs of biomass synthesis (SC). From the responses of biomass and yield to late N applications and the apparent contribution of mobilised biomass to yield, it seems that the yield of oilseed rape was more source-limited during grain filling than that of wheat, particularly at the medium and high N levels. Both species recovered equal amounts of N from the total available N in the soil and had similar N use efficiencies, expressed as yield per unit of N absorbed. However, oilseed rape had higher efficiency to convert absorbed N in biomass, but lower harvest index of N than wheat. Oilseed rape had similar or lower root biomass than wheat, depending on N level, but higher root length per unit soil volume and specific root length. The specific uptake rate of N per unit root dry weight during the critical period for grain number determination was higher in oilseed rape than in wheat. In wheat, N limitation affected growth through a similar or lower reduction in radiation use efficiency corrected for synthesis costs (RUESC) than in the cumulative amount of intercepted photosynthetically active radiation (IPARc). In oilseed rape, lower growth due to N shortage was associated more with RUESC than IPARc, during flowering while during grain filling both components contributed similarly to decreased growth. RUESC and the concentration of N in leaves and inflorescence (LIN€decreased from flowering to maturity and were curvilinearly related. Oilseed rape tended to have higher RUESC than wheat at high N supply during the critical period for grain number determination, and generally lower during grain filling. The reasons for these differences and possibilities to increase yield potential are discussed in terms of the photosynthetic efficiency of the different organs and changes in source–sink ratio during reproductive stages