Carlos Busanello

Eficiência do uso da radiação solar por plantas Ilex paraguariensis A. St. Hil. cultivadas sob sombreamento e a pleno sol

The efficiency of conversion of the solar radiation in biomass is a variable frequently used in models of simulation the culture growth, because the biomass production is related with the efficiency of which a plant converts radiant energy in chemistry, given by the process of the photosynthesis. The objective of this work was to determine the efficiency of conversion of the photosynthetically active and intercepted solar radiation (RFAi) in Ilex paraguariensis biomass, cultivated in consortium (Ilex paraguariensis A. St. Hil. E Pinus elliottii Engelm) and single. For so much, it was determined the photosynthetically active and intercepted solar radiation (RFAi), the index of leaf area and the biomass dries of the seedlings, being then, the efficiency of conversion of RFAi in biomass dries of the cultivated in consortium and single. For a same radiation value RFAi, is obtained larger efficiency of use of the radiation in the accumulation in matter dries when Ilex paraguariensis is cultivated in consortium. The conversion efficiency (eb) of biomass total drought of Ilex paraguariensis plants in relation to the amount of the photosynthetically active and intercepted solar radiation (RFAi) accumulated is of 0.83 g MJ-1 in the system consortium and of 0.23 g MJ-1 in the single system. In spite of that, the production of aerial biomass for plant was larger in the single system.

Seed germination and seedling growth of canola treated with abiotic factors that can affect growth and development.

ABSTRACT Canola (Brassica napus L. var. oleifera) is a source of vegetable oil. Abiotic factors may have negative impact on canola productivity. This study evaluated responses of canola hybrids under simulated flooding and drought and excess salinity. Evaluations were performed at 7 and 14 days after germination analyzing the variables percent of germinated seed, shoot length, root length, shoot dry weight, and root dry weight measured. Simulated flooding and drought and salinity detrimentally affected canola germination and initial development. Genotype expressed genetic variability for tolerance to simulated flooding and drought and salinity. The genotype “Hyola 575CL” was less sensitive to simulated drought and flooding and excess salinity.

Activation of rice WRKY transcription factors: an army of stress fighting soldiers?

Rice WRKYs comprise a large family of transcription factors and present remarkable structure features and a unique DNA binding site. Their importance in plants goes beyond the response to stressful stimuli, since they participate in hormonal pathways and developmental processes. Indeed, the majority of WRKYs present an independent activation since they are able to perform self-transcriptional regulation. However, some WRKY activation depends on epigenetic and transcript regulation by micro RNAs. Their protein function depends, almost always, on the posttranslational changes. Taking to account its properties of auto-activation, all these regulators process are extremely important for complete WRKY regulation. In this sense, here we provide an overview of transcriptional activation and posttranscriptional and posttranslational regulation of rice WRKY genes under stresses.

Regulation of rice responses to submergence by WRKY transcription factors

Responses of rice to submergence have been extensively studied, but the molecular network behind the tolerance to this stress is still incomplete. Transcription factors (TFs) are important players in gene transcription regulation during stresses. Here, we analyzed expression of WRKY genes and morphological and anatomical changes in different rice cultivars under submergence. When they were submerged for 48 h, changes in root number, fresh and dry masses, and aerenchyma development were observed. Although accumulations of WRKY transcripts were observed in both shoots and roots, root tissues showed higher accumulation with a peak already after 6 h under submergence. Especially transcriptions of OsWRKY11 and OsWRKY56 were high, more than 100-fold in comparison with controls. The WRKY promoter analysis showed that some cis-regulatory elements could be characterized as stress-responsive elements and linked to oxygen depletion. In the promoter of OsWRKY62, two cis-regulatory elements were found: ARE and GC-motif. These elements are known to be involved in oxygen deficiency responses. In addition, the W-box cis-regulatory element, the target of WRKY transcription factors, was found in OsWRKY11, OsWRKY56, and OsWRKY62, suggesting a feedback control acting on the upregulation of WRKY transcription factors. Genes involved in the submergence stress and resulting aerenchyma development had a W-box in their promoter regions, which also suggested regulation by WRKYs. Overall, the results support the role of WRKY transcription factors in rice submergence tolerance and unveil their action in other tolerance mechanisms.

Iron excess in rice: from phenotypic changes to functional genomics of WRKY transcription factors

Iron (Fe) is an essential microelement for all living organisms playing important roles in several metabolic reactions. Rice (Oryza sativa L.) is commonly cultivated in paddy fields, where Fe goes through a reduction reaction from Fe3+ to Fe2+. Since Fe2+ is more soluble, it can reach toxic levels inside plant cells, constituting an important target for studies. Here we aimed to verify morphological changes of different rice genotypes focusing on deciphering the underlying molecular network induced upon Fe excess treatments with special emphasis on the role of four WRKY transcription factors. The transcriptional response peak of these WRKY transcription factors in rice seedlings occurs at 4 days of exposition to iron excess. OsWRKY55-like, OsWRKY46, OsWRKY64, and OsWRKY113 are up-regulated in BR IRGA 409, an iron-sensitive genotype, while in cultivars Nipponbare (moderately resistant) and EPAGRI 108 (resistant) the expression profiles of these transcription factors show similar behaviors. Here is also shown that some cis-regulatory elements known to be involved in other different stress responses can be linked to conditions of iron excess. Overall, here we support the role of WRKY transcription factors in iron stress tolerance with other important steps toward finding why some rice genotypes are more tolerant than others.