Identification of a seed maturation protein gene from Coffea arabica (CaSMP) and analysis of its promoter activity in tomato.

KEY MESSAGE: A seed maturation protein gene (CaSMP) from Coffea arabica is expressed in the endosperm of yellow/green fruits. The CaSMP promoter drives reporter expression in the seeds of immature tomato fruits. In this report, an expressed sequence tag-based approach was used to identify a seed-specific candidate gene for promoter isolation in Coffea arabica. The tissue-specific expression of the cognate gene (CaSMP), which encodes a yet uncharacterized coffee seed maturation protein, was validated by RT-qPCR. Additional expression analysis during coffee fruit development revealed higher levels of CaSMP transcript accumulation in the yellow/green phenological stage. Moreover, CaSMP was preferentially expressed in the endosperm and was down-regulated during water imbibition of the seeds. The presence of regulatory cis-elements known to be involved in seed- and endosperm-specific expression was observed in the CaSMP 5'-upstream region amplified by genome walking (GW). Additional histochemical analysis of transgenic tomato (cv. Micro-Tom) lines harboring the GW-amplified fragment (~ 1.4 kb) fused to uidA reporter gene confirmed promoter activity in the ovule of immature tomato fruits, while no activity was observed in the seeds of ripening fruits and in the other organs/tissues examined. These results indicate that the CaSMP promoter can be used to drive transgene expression in coffee beans and tomato seeds, thus representing a promising biotechnological tool.

Promoter analysis of the WRKY transcription factors CaWRKY1a and CaWRKY1b homoeologous genes in coffee (Coffea arabica).

KEY MESSAGE: The regulation of the CaWRKY1 homoeologous genes were analyzed through the characterization of their promoters. The pW1a promoter is proposed as a new tool for coffee plant biotechnologies. WRKY transcription factors are important elements of the plant immune response. The CaWRKY1 gene from Coffea arabica is induced by several biotic and abiotic stresses, including challenge by the rust fungus Hemileia vastatrix. Two homoeologous CaWRKY1 genes, named CaWRKY1a and CaWRKY1b, were previously identified in the C. arabica allotetraploid genome. To gain insight into the transcriptional regulation of these genes, their promoter sequences, named pW1a and pW1b, respectively, were cloned and characterized in this study. In silico analysis revealed some important defense-associated regulatory elements, including W-boxes and as-1 elements. Promoter activities were analyzed in transient assays conducted by agroinfiltration of tobacco leaves. Exogenous salicylic acid (SA) treatments increased promoter activities corroborating the presence of as-1 regulatory elements. Transactivation assays with the CaWRKY1 protein showed the reduction of both pW1a and pW1b promoter activities, indicating that the CaWRKY1 protein may negatively regulate its own promoters. Stable transgenic C. arabica lines expressing a pW1a::GUS construct were obtained by Agrobacterium-mediated transformation and high GUS activity was observed in leaves subjected to mechanical wounding. Hence, the ability of pW1a to drive transgene expression in coffee plants as well as to enhance expression in response to stresses opens possibilities for using this promoter as a new tool for biotechnological approaches in coffee plants.

Identification of suitable internal control genes for expression studies in Coffea arabica under different experimental conditions.

BACKGROUND: Quantitative data from gene expression experiments are often normalized by transcription levels of reference or housekeeping genes. An inherent assumption for their use is that the expression of these genes is highly uniform in living organisms during various phases of development, in different cell types and under diverse environmental conditions. To date, the validation of reference genes in plants has received very little attention and suitable reference genes have not been defined for a great number of crop species including Coffea arabica. The aim of the research reported herein was to compare the relative expression of a set of potential reference genes across different types of tissue/organ samples of coffee. We also validated the expression profiles of the selected reference genes at various stages of development and under a specific biotic stress. RESULTS: The expression levels of five frequently used housekeeping genes (reference genes), namely alcohol dehydrogenase (adh), 14-3-3, polyubiquitin (poly), beta-actin (actin) and glyceraldehyde-3-phosphate dehydrogenase (gapdh) was assessed by quantitative real-time RT-PCR over a set of five tissue/organ samples (root, stem, leaf, flower, and fruits) of Coffea arabica plants. In addition to these commonly used internal controls, three other genes encoding a cysteine proteinase (cys), a caffeine synthase (ccs) and the 60S ribosomal protein L7 (rpl7) were also tested. Their stability and suitability as reference genes were validated by geNorm, NormFinder and BestKeeper programs. The obtained results revealed significantly variable expression levels of all reference genes analyzed, with the exception of gapdh, which showed no significant changes in expression among the investigated experimental conditions. CONCLUSION: Our data suggests that the expression of housekeeping genes is not completely stable in coffee. Based on our results, gapdh, followed by 14-3-3 and rpl7 were found to be homogeneously expressed and are therefore adequate for normalization purposes, showing equivalent transcript levels in different tissue/organ samples. Gapdh is therefore the recommended reference gene for measuring gene expression in Coffea arabica. Its use will enable more accurate and reliable normalization of tissue/organ-specific gene expression studies in this important cherry crop plant.