ABSTRACT
ABSTRACT: Gene stacking refers to the introduction of two or more transgenes of agronomic interest in the same plant. The main methods for genetically engineering plants with gene stacking involve (i) the simultaneous introduction, by the co-transformation process, and (ii) the sequential introduction of genes using the re-transformation processes or the sexual crossing between separate transgenic events. In general, the choice of the best method varies according to the species of interest and the availability of genetic constructions and preexisting transgenic events. We also present here the use of minichromosome technology as a potential future gene stacking technology. The purpose of this review was to discuss aspects related to the methodology for gene stacking and trait stacking (a gene stacking strategy to combine characteristics of agronomical importance) by genetic engineering. In addition, we presented a list of crops and genes approved commercially that have been used in stacking strategies for combined characteristics and a discussion about the regulatory standards. An increased number of approved and released gene stacking events reached the market in the last decade. Initially, the most common combined characteristics were herbicide tolerance and insect resistance in soybean and maize. Recently, commercially available varieties were released combining these traits with drought tolerance in these commodities. New traits combinations are reaching the farmer's fields, including higher quality, disease resistant and nutritional value improved. In other words, gene stacking is growing as a strategy to contribute to food safety and sustainability.
RESUMO: O empilhamento gênico se refere a introdução de dois ou mais transgenes de interesse agronômico na mesma planta. Os principais métodos de produção de plantas geneticamente modificadas com empilhamento gênico envolvem (i) a introdução simultânea, pelo processo de co-transformação, e (ii) a introdução sequencial de genes, pelos processos de re-transformação ou por cruzamento entre eventos transgênicos. Em geral, a escolha do melhor método varia de acordo com a espécie de interesse e a disponibilidade de construções genéticas e eventos transgênicos preexistentes. Também é apresentado aqui o uso da tecnologia de minicromossomos como tecnologia potencial de empilhamento gênico. O objetivo desta revisão é discutir aspectos relacionados à metodologia para o empilhamento de genes a combinação de características (obtida via empilhamento de genes de interesse agronômico) via engenharia genética. Além de discutir, é apresentado uma lista de culturas e genes aprovados comercialmente que tem sido usado em estratégias de empilhamento e uma discussão sobre normas regulatórias. Um número maior de eventos com empilhamento de genes foi aprovado e liberado no mercado na última década. Inicialmente, a combinação das características de tolerância a herbicidas e resistência a insetos era a mais popular, principalmente em soja e milho. Recentemente, estas características combinadas com tolerância a seca nessas culturas foram liberadas comercialmente. Novas características combinadas estão entrando na lavoura, incluindo aumento da qualidade, resistência a doenças e aumento do valor nutricional. Em outras palavras, o empilhamento gênico está crescendo como tecnologia para contribuir para a segurança alimentar e sustentabilidade.
ABSTRACT
Abstract sn-Glycerol-3-phosphate 1-O-acyltransferase (GPAT) is an important enzyme that catalyzes the transfer of an acyl group from acyl-CoA or acyl-ACP to the sn-1 or sn-2 position of sn-glycerol-3-phosphate (G3P) to generate lysophosphatidic acids (LPAs). The functional studies of GPAT in plants demonstrated its importance in controlling storage and membrane lipid. Identifying genes encoding GPAT in a variety of plant species is crucial to understand their involvement in different metabolic pathways and physiological functions. Here, we performed genome-wide and evolutionary analyses of GPATs in plants. GPAT genes were identified in all algae and plants studied. The phylogenetic analysis showed that these genes group into three main clades. While clades I (GPAT9) and II (soluble GPAT) include GPATs from algae and plants, clade III (GPAT1-8) includes GPATs specific from plants that are involved in the biosynthesis of cutin or suberin. Gene organization and the expression pattern of GPATs in plants corroborate with clade formation in the phylogeny, suggesting that the evolutionary patterns is reflected in their functionality. Overall, our results provide important insights into the evolution of the plant GPATs and allowed us to explore the evolutionary mechanism underlying the functional diversification among these genes.
ABSTRACT
Abstract Plinia trunciflora is a Brazilian native fruit tree from the Myrtaceae family, also known as jaboticaba. This species has great potential by its fruit production. Due to the high content of essential oils in their leaves and of anthocyanins in the fruits, there is also an increasing interest by the pharmaceutical industry. Nevertheless, there are few studies focusing on its molecular biology and genetic characterization. We herein report the complete chloroplast (cp) genome of P. trunciflora using high-throughput sequencing and compare it to other previously sequenced Myrtaceae genomes. The cp genome of P. trunciflora is 159,512 bp in size, comprising inverted repeats of 26,414 bp and single-copy regions of 88,097 bp (LSC) and 18,587 bp (SSC). The genome contains 111 single-copy genes (77 protein-coding, 30 tRNA and four rRNA genes). Phylogenetic analysis using 57 cp protein-coding genes demonstrated that P. trunciflora, Eugenia uniflora and Acca sellowiana form a cluster with closer relationship to Syzygium cumini than with Eucalyptus. The complete cp sequence reported here can be used in evolutionary and population genetics studies, contributing to resolve the complex taxonomy of this species and fill the gap in genetic characterization.
ABSTRACT
Abstract Soybean, a crop known by its economic and nutritional importance, has been the subject of several studies that assess the impact and the effective plant responses to abiotic stresses. Salt stress is one of the main environmental stresses and negatively impacts crop growth and yield. In this work, the RNA editing process in the chloroplast of soybean plants was evaluated in response to a salt stress. Bioinformatics approach using sRNA and mRNA libraries were employed to detect specific sites showing differences in editing efficiency. RT-qPCR was used to measure editing efficiency at selected sites. We observed that transcripts of NDHA, NDHB, RPS14 and RPS16 genes presented differences in coverage and editing rates between control and salt-treated libraries. RT-qPCR assays demonstrated an increase in editing efficiency of selected genes. The salt stress enhanced the RNA editing process in transcripts, indicating responses to components of the electron transfer chain, photosystem and translation complexes. These increases can be a response to keep the homeostasis of chloroplast protein functions in response to salt stress.
ABSTRACT
Habitat fragmentation and a decrease in population size may lead to a loss in population genetic diversity. For the first time, the reduction in genetic diversity in the northernmost limit of natural occurence (southeastern Brazil) of Araucaria angustifolia in comparison with populations in the main area of the species continuous natural distribution (southern Brazil), was tested. The 673 AFLPs markers revealed a high level of genetic diversity for the species (Ht = 0.27), despite anthropogenic influence throughout the last century, and a decrease of H in isolated populations of southeastern Brazil (H = 0.16), thereby indicating the tendency for higher genetic diversity in remnant populations of continuous forests in southern Brazil, when compared to natural isolated populations in the southeastern region. A strong differentiation among southern and southeastern populations was detected (AMOVA variance ranged from 10 percent-15 percent). From Bayesian analysis, it is suggested that the nine populations tested form five "genetic clusters" (K = 5). Five of these populations, located in the northernmost limit of distribution of the species, represent three "genetic clusters". These results are in agreement with the pattern of geographic distribution of the studied populations.
Subject(s)
Tracheophyta/genetics , Genetic Variation , Genetics, Population , Amplified Fragment Length Polymorphism Analysis , Bayes Theorem , BrazilABSTRACT
The occurrence of quasi-repetitive glycine-rich peptides has been reported in different organisms. Glycine-rich regions are proposed to be involved in protein-protein interactions in some mammalian protein families. In plants, a set of glycine-rich proteins (GRPs) was characterized several years ago, and since then a wealth of new GRPs have been identified. GRPs may have very diverse sub-cellular localization and functions. The only common feature among all different GRPs is the presence of glycine-rich repeat domains. The expression of genes encoding GRPs is developmentally regulated, and also induced, in several plant genera, by physical, chemical and biological factors. In addition to the highly modulated expression, several GRPs also show tissue-specific localization. GRPs specifically expressed in xylem, phloem, epidermis, anther tapetum and roots have been described. In this paper, the structural and functional features of these proteins in Eucalyptus are summarized. Since this is the first description of GRPs in this species, particular emphasis has been given to the expression pattern of these genes by analyzing their abundance and prevalence in the different cDNA-libraries of the Eucalyptus Genome Sequencing Project Consortium (ForEST). The comparison of GRPs from Eucalyptus and other species is also discussed
Subject(s)
Eucalyptus , Expressed Sequence Tags , Glycine , Databases, Genetic , Plant ProteinsABSTRACT
MADS-box genes encode a family of transcription factors which control diverse developmental processes in flowering plants ranging from root to flower and fruit development. Members of the MADS-box gene family share a highly conserved sequence of approximately 180 nucleotides that encodes a DNA-binding domain. We used bioinformatics tools to investigate the information generated by the Eucalyptus Expressed Sequence Tag (FORESTs) genome project in order to identify and annotate MADS-box genes. The comparative phylogenetic analysis of the Eucalyptus MADS-box genes with Arabidopsis homologues allowed us to group them into one of the well-known subfamilies. Trends in gene expression of these putative Eucalyptus MADS-box genes were investigated by hierarchical clustering analysis. Among 24 MADS-box genes identified by our analysis, 12 are expressed in vegetative organs. Out of these, five are expressed predominately in wood. Understanding of the molecular mechanisms performed by MADS-box proteins underlying Eucalyptus growth, development and stress reactions would provide important insights into tree development and could reveal means by which tree characteristics could be modified for the improvement of industrial properties
Subject(s)
Eucalyptus/genetics , MADS Domain Proteins , Databases, Genetic , Expressed Sequence Tags , Phylogeny , Plants/growth & development , Plants/genetics , Transcription FactorsABSTRACT
The expression of AtchitIV gene was analysed in Arabidopsis plants submitted to abiotic stresses. Transcript accumulation was detected in leaves in response to UV light exposure, exogenous salicylic acid administration and wounding. Transgenic Arabidopsis plants carrying AtchitIV promoter::gus fusion also showed differential expression of the reporter gene in response to these treatments. The AtchitIV expression was also analysed during Arabidopsis embryo development. GUS assay demonstrated AtchitIV promoter activation in zygotic embryos from torpedo stage up to full maturation. Promoter deletion analysis indicated that all the 5' cis-acting elements responsible for the specific tissue expression are located in a region of 1083 bp, adjacent to the start of transcription. A negative regulatory region located between portions -1083 and -600 was also observed.
Subject(s)
Arabidopsis , Gene Expression , Promoter Regions, Genetic , Arabidopsis , Plants, Genetically Modified , Stress, MechanicalABSTRACT
Desde o isolamento da primeira proteína rica em glicina (GRP) em plantas, um grande número de novas GRPs vem sendo identificado. Seu padräo de expressäo altamente específico, embora variado, em conjunto com as diferentes localizações sub-celulares de alguns dos tipos de GRPs, claramente indica que estas proteínas encontram-se envolvidas em diversos processos fisiológicos independentes. Embora ainda sem uma clara definiçäo do papel de GRPs na célula vegetal, estudos realizados com estas proteínas têm resultado em novos e interessantes esclarecimentos da biologia celular e molecular de plantas. Promotores com regulaçäo complexa, assim como distintos mecanismos de regulaçäo da expressäo gênica tem sido demonstrados. Novas vias de endereçamento de proteínas tais como a exportaçäo de GRPs para diferentes tipos celulares, tem sido observados. Estes dados mostram que as GRPs podem constituir marcadores e/ou modelos interessantes para a compreensäo de distintos aspectos da biologia vegetal. Neste trabalho, características estruturais e funcionais deste tipo de proteínas em cana-de-açúcar (Saccharum officinarum L.) foram analisadas. Uma vez que esta é a primeira descriçäo deste tipo de proteínas, em cana-de-açúcar, especial atençäo foi dada para o padräo de expressäo destes genes, analisando-se a abundância e prevalência de cada um dos genes nas diferentes bibliotecas de cDNA do projeto Sequenciamento de ESTs de cana-de-açúcar (SUCEST). A comparaçäo das GRPs de cana-de-açúcar com as GRPs descritas em outras espécies também será discutida.
Subject(s)
Expressed Sequence Tags , Plant Proteins/genetics , PlantsABSTRACT
Proteinases cisteínicas säo peptidil-hidrolases dependentes de um resíduo de cisteína em seu sítio ativo. As propriedades físico-químicas destas proteinases têm sido amplamente caracterizadas, entretanto suas funções biológicas ainda näo foram completamente elucidadas. Elas estäo envolvidas em um grande número de eventos, tais como: processamento e degradaçäo protéica, câncer, germinaçäo, morte celular programada e processos de senescência. Diferentes proteinases cisteínicas, classificadas pelo Comitê de Nomenclatura da Uniäo Internacional de Bioquímica e Biologia Molecular (IUBMB) como pertencentes à sub-sub-classe E.C.3.4.22, foram usadas na busca de clusters no banco de dados do SUCEST (SUgarCane EST project), utilizando-se o programa T-BLAST-n. Homologia de seqüências foram encontradas com 76 clusters que correspondem a prováveis proteinases cisteínicas. O alinhamento destas seqüências com a de outras proteases cisteínicas, de diversas origens, forneceu informaçäo quanto à classificaçäo e possível funçäo das proteinases de cana-de-açúcar. Além disso, o padräo de expressäo de cada gene foi postulado a partir da correlaçäo direta com as bibliotecas de cDNA do SUCEST dos quais os clusters foram derivados. Uma vez que nenhum gene de protease cisteínica foi anteriormente evidenciado em cana-de-açúcar, este estudo representa uma etapa inicial para o estudo de novos aspectos bioquímicos, fisiológicos e biotecnológicos destas enzimas.
Subject(s)
Animals , Cysteine Endopeptidases/classification , Plant Proteins/classification , Databases as Topic , Expressed Sequence Tags , Plant Proteins/geneticsABSTRACT
As cistatinas säo inibidores competitivos e reversíveis de proteinases cisteínicas, compondo uma superfamília de proteínas evolutivamente relacionadas. Esta superfamília está dividida em três famílias: a primeira, das estefinas, é composta de proteínas destituídas de pontes de enxofre; a segunda, das cistatinas, agrupa proteínas que possuem pontes de sulfeto; a terceira família, dos kininogênios, se caracteriza por ser formada por glicoproteínas de alto peso molecular com três domínios repetidos similares aos da família das cistatinas. As fitocistatinas constituem uma família de cistatinas que possui representantes exclusivamente em plantas. Elas säo proteínas que näo possuem pontes de enxofre e contém uma seqüência conservada L-A-R-[FY]-A-[VI]-X3-N na regiäo N-terminal. Neste trabalho nós usamos seqüências derivadas de sete fitocistatinas, identificadas no projeto genoma de Arabidopsis, para identificar possíveis membros da superfamília das cistatinas presentes no banco de dados de cana-de-açúcar do SUCEST. Foram identificadas vinte e cinco possíveis fitocistatinas de cana-de-açúcar. Uma análise filogenética permitiu agrupar as fitocistatinas em quatro grupos: (i) contendo o consenso N-terminal; (ii) contendo o consenso N-terminal e mais uma extensäo C-terminal; (iii) destituído do consenso N-terminal e (iv) destituído do consenso N-terminal e do motivo conservado QxVxG encontrado em todos os membros da superfamília.