Gene structure and potential regulation of the lycopene cyclase genes in Bixa orellana L.

Lycopene cyclases (LCYs) are a key branching point in regulating the carotenoid biosynthesis pathway in plants. Bixa orellana L. is characterized by the presence in its seed of bixin, an apocarotenoid of significant importance in the food, pharmaceutical, and cosmetic industries. Gene analysis provides the opportunity to investigate the LCY gene structure in plant species and its relationship with the synthesis of carotenoids. Coding sequences of the LCY genes were retrieved from a B. orellana genome DNA. Boß-LCY1 and Boß-LCY2 genes exhibit 100% of identity to their respective cDNA accessions, and exhibit a single coding region of 1512 bp (504 aa) and 1495 bp (498 aa), respectively. In contrast, Boε-LCY gene shows a coding region of 1581 bp (527 aa) with 10 introns of diverse lengths. Putative Transcription Factors (TFs) binding sites were upstream (3000 bp) identified for each LCY gene. TFs cover two groups, one with the categories of photosynthesis, reproduction, and oxidative processes that are frequent. The second one with the categories of defense, cell cycle, signaling, and carbohydrate metabolism, which are poorly represented. Besides, repetitive DNA elements showed motifs and proteins related to LTR from the Ty3/Gypsy family, were associated with the TFs regions. In general, TFs vary in the different BoLCY genes, being more abundant in the Boε-LCY gene. LCY expression analyzed from a transcriptome database, and validated by RT-qPCR, shows an upregulation of the three LCYs, mainly oriented to the synthesis of essential carotenoids in photosynthetic tissues (leaves), as well as an upregulation of the Boß-LCY2 gene in the non-photosynthetic tissues (firsts seed development stages) related to the bixin accumulation. Supplementary Information: The online version contains supplementary material available at 10.1007/s12298-023-01384-8.

Gene expression analysis during the fruit development in dehiscent and indehiscent Bixa orellana L. accessions.

Fruit morphology and dehiscence-related genes were analyzed in dehiscent N4P and dehiscent P12 Bixa orellana accessions. Fruit architecture (exocarp and pericarp cells, trichomes, vascular bundles, vesicles, and bixin cells) documented by Scanning electron microscopy (SEM) morphology, blue toluidine stain, and phloroglucinol and hydrochloric acid (PHCL) stain was similar in both accessions. Although, the dehiscent zone (DZ) was higher in the indehiscent P12 B. orellana accession, lignification values, obtained by phloroglucinol and hydrochloric acid stain, within the DZ remain was similar in both variants being lower at 34 days after floral anthesis in the dehiscent N4P B. orellana accession. Dehiscence-related genes APETALA (AP2), SHATTERPROOF (SHP), and SPATULA (SPT) were identified on the reported B. orellana transcriptome (SRX1117606). Real-time quantitative polymerase chain reaction primers build by using these genes allow observing a differential expression during six fruit development stages. In both B. orellana accessions, the AP2 transcripts have a reduced expression, whereas the SHP transcripts were significantly higher during the first two days and ten days of development. SPT transcripts show an expression differential between both accessions being significantly higher in the dehiscent N4P, peaking with 9.66% at 42 days after floral anthesis (DAFA) of development. SPT transcription profile suggested that this gene has an important role during the fruit opening in the dehiscent N4P B. orellana accession. Supplementary Information: The online version contains supplementary material available at 10.1007/s12298-022-01180-w.

Retroelements and DNA Methylation Could Contribute to Diversity of 5S rDNA in Agave L.

Agave L. is a genus of economic importance, and many of the 166 species in the American plant genus Agave L. inhabit high-stress environments, which makes the genus promising for facing global climate change. However, sustainable use of economically important species without interfering with their ecology and evolution requires generating knowledge about the factors responsible for their genetic variation and diversity and, on this basis, their adaptation and speciation. Few genetic studies exploring the evolutionary relationships, speciation processes, genetic variability and diversity within species of Agave are currently available. Analyses of rDNA loci have been performed with the purpose of determining the genetic variability and diversity of the genus Agave, and these loci have been used as genetic markers of ploidy. However, the factors involved in the diversity of 5S rDNA regions in Agave have not yet been studied in depth. Our study explored the possible mechanisms of genetic (retroelements) and epigenetic (DNA methylation) diversity in 5S rDNA regions in Agave. We characterized the 5S rDNA gene tandem in species of the genus with different ploidy numbers and determined the levels of methylation in 13 haplotypes of 5S rDNA and in four non-transcribed spacers (NTS). Our results showed highly dynamic methylation with a high percentage in haplotypes and NTS of 5S rDNA regions in Agave. The characterization of the 5S rDNA tandem array in Agave revealed vestigial remains of the Cassandra terminal-repeat retrotransposon in miniature (TRIM). Our analysis supported previous results suggesting that in species of Agave L., regulation and diversity of 5S rDNA regions are controlled by coordinated genetic and epigenetic events, which will vary according to the species and the level of ploidy. The artificial pressure to which some agave crops are subjected may affect the mechanisms of evolution of gene 5S rDNA.

Morphological features of different polyploids for adaptation and molecular characterization of CC-NBS-LRR and LEA gene families in Agave L.

Polyploidy has been widely described in many Agave L. species, but its influence on environmental response to stress is still unknown. With the objective of knowing the morphological adaptations and regulation responses of genes related to biotic (LEA) and abiotic (NBS-LRR) stress in species of Agave with different levels of ploidy, and how these factors contribute to major response of Agave against environmental stresses, we analyzed 16 morphological trials on five accessions of three species (Agave tequilana Weber, Agave angustifolia Haw. and Agave fourcroydes Lem.) with different ploidy levels (2n=2x=60 2n=3x=90, 2n=5x=150, 2n=6x=180) and evaluated the expression of NBS-LRR and LEA genes regulated by biotic and abiotic stress. It was possible to associate some morphological traits (spines, nuclei, and stomata) to ploidy level. The genetic characterization of stress-related genes NBS-LRR induced by pathogenic infection and LEA by heat or saline stresses indicated that amino acid sequence analysis in these genes showed more substitutions in higher ploidy level accessions of A. fourcroydes Lem. 'Sac Ki' (2n=5x=150) and A. angustifolia Haw. 'Chelem Ki' (2n=6x=180), and a higher LEA and NBS-LRR representativeness when compared to their diploid and triploid counterparts. In all studied Agave accessions expression of LEA and NBS-LRR genes was induced by saline or heat stresses or by infection with Erwinia carotovora, respectively. The transcriptional activation was also higher in A. angustifolia Haw. 'Chelem Ki' (2n=6x=180) and A. fourcroydes 'Sac Ki' (2n=5x=150) than in their diploid and triploid counterparts, which suggests higher adaptation to stress. Finally, the diploid accession A. tequilana Weber 'Azul' showed a differentiated genetic profile relative to other Agave accessions. The differences include similar or higher genetic representativeness and transcript accumulation of LEA and NBS-LRR genes than in polyploid (2n=5x=150 and 2n=6x=180) Agave accessions, thus suggesting a differentiated selection pressure for overcoming the lower ploidy level of the diploid A. tequilana Weber 'Azul'.

Identification and expression pattern of a new carotenoid cleavage dioxygenase gene member from Bixa orellana.

Carotenoid cleavage dioxygenases (CCDs) are a class of enzymes involved in the biosynthesis of a broad diversity of secondary metabolites known as apocarotenoids. In plants, CCDs are part of a genetic family with members which cleave specific double bonds of carotenoid molecules. CCDs are involved in the production of diverse and important metabolites such as vitamin A and abscisic acid (ABA). Bixa orellana L. is the main source of the natural pigment annatto or bixin, an apocarotenoid accumulated in large quantities in its seeds. Bixin biosynthesis has been studied and the involvement of a CCD has been confirmed in vitro. However, the CCD genes involved in the biosynthesis of the wide variety of apocarotenoids found in this plant have not been well documented. In this study, a new CCD1 gene member (BoCCD1) was identified and its expression was charaterized in different plant tissues of B. orellana plantlets and adult plants. The BoCCD1 sequence showed high homology with plant CCD1s involved mainly in the cleavage of carotenoids in several sites to generate multiple apocarotenoid products. Here, the expression profiles of the BoCCD1 gene were analysed and discussed in relation to total carotenoids and other important apocarotenoids such as bixin.

Recent advances and novel applications in microbial diversity estimation based on DNA analysis methods.

This review focuses on recent patents on the exploration and quantification of microbial diversity. Only the patents based on DNA analysis are considered. In general terms, the analysis of environmental samples can be investigated by using three main approaches: microarrays based technologies, genomes/metagenomes comparison and amplification and detection of operative taxonomic units. All patents can relate to the estimation of the microbial diversity, however, many of them were initially designed to detect important medical or agronomic microorganisms. Here, we briefly review recent technological achievements for DNA analysis that offer great potentials for the identification of species.

Culture-independent analysis of lactic acid bacteria diversity associated with mezcal fermentation.

Mezcal is an alcoholic beverage obtained from the distillation of fermented juices of cooked Agave spp. plant stalks (agave must), and each region in Mexico with denomination of origin uses defined Agave species to prepare mezcal with unique organoleptic characteristics. During fermentation to produce mezcal in the state of Tamaulipas, not only alcohol-producing yeasts are involved, but also a lactic acid bacterial community that has not been characterized yet. In order to address this lack of knowledge on this traditional Mexican beverage, we performed a DGGE-16S rRNA analysis of the lactic acid bacterial diversity and metabolite accumulation during the fermentation of a typical agave must that is rustically produced in San Carlos County (Tamaulipas, Mexico). The analysis of metabolite production indicated a short but important malolactic fermentation stage not previously described for mezcal. The denaturing gradient gel electrophoresis (DGGE) analysis of the 16S rRNA genes showed a distinctive lactic acid bacterial community composed mainly of Pediococcus parvulus, Lactobacillus brevis, Lactobacillus composti, Lactobacillus parabuchneri, and Lactobacillus plantarum. Some atypical genera such as Weissella and Bacillus were also found in the residual must. Our results suggest that the lactic acid bacteria could strongly be implicated in the organoleptic attributes of this traditional Mexican distilled beverage.

Agaves as a raw material: recent technologies and applications.

Agave plants are a valuable source of raw material due to its fibrous and complex sugar content of their leaves and core, and their bagasse waste can be use for several aims. This plant genus belongs to the Agavaceae family and until now more than 200 species have been described. A large number of Agave species are currently used as raw material in several biotechnological processes. This review shows the reported applications and patents on fields like alcoholic brewages with special reference to Tequila and Mezcal, the isolation and use of compounds such as saponins and agave fructans, and their potential biotechnological application on several human demands. The process to obtain fibers and cellulose, stock feeds, and several miscellaneous extractives are also reviewed. Some possibilities and problems of cultivation are discussed.

Full-Length gene enrichment by using an optimized RNA isolation protocol in Bixa orellana recalcitrant tissues.

A reliable protocol is described for isolation of large full-length cDNA from Bixa orellana mature tissues containing large quantities of pigments, phenols, and polysaccharides. This protocol involves the optimization of a commercial RNA extraction protocol in combination with a long distance reverse transcript PCR protocol. The principal advantages of this protocol are its high RNA yield and quality. The resulting RNA is suitable for RNA expression evaluation and production of large, full-length cDNA. This is the first time RNA has been isolated from all mature tissues in the tropical perennial plant B. orellana and has been proved viable for downstream applications, especially important for molecular biology studies on this economically important pigment-producing plant.

Biocontrol potential and polyphasic characterization of novel native Trichoderma strains against Macrophomina phaseolina isolated from sorghum and common bean.

Native strains of Trichoderma isolated from sorghum and common bean crop soils were investigated to assess their biocontrol potential over the phytopathogenic fungus Macrophomina phaseolina, isolated from diseased plants. The Trichoderma strains were characterized with a polyphasic approach, which combined the analysis of their morphological characteristics, enzymatic activity, macro- and microculture test results, rDNA restriction patterns (AFLP), ITS1-5.8S-ITS2 rDNA sequences, and protein profiles. The integration of these data sets can be used to select new isolates as biological control agents against native fungal phytopathogens. In general, we observed a positive correlation between the secretion of beta-1,3-glucanase and N-acetylhexosaminidase, and the biocontrol capacities of all the Trichoderma isolates. Strains with the best hyperparasitic behavior against M. phaseolina isolated from diseased bean and sorghum were Trichoderma sp. (TCBG-2) and Trichoderma koningiopsis (TCBG-8), respectively.