Molecular and Metabolic Mechanisms Associated with Fleshy Fruit QualityAna M. Fortes, Antonio Granell, Mario Pezzotti, Mondher Bouzayen Frontiers Media SA, Sep 8, 2017 Fleshy Fruits are a late acquisition of plant evolution. In addition of protecting the seeds, these specialized organs unique to plants were developed to promote seed dispersal via the contribution of frugivorous animals. Fruit development and ripening is a complex process and understanding the underlying genetic and molecular program is a very active field of research. Part of the ripening process is directed to build up quality traits such as color, texture and aroma that make the fruit attractive and palatable. As fruit consumers, humans have developed a time long interaction with fruits which contributed to make the fruit ripening attributes conform our needs and preferences. This issue of Frontiers in Plant Science is intended to cover the most recent advances in our understanding of different aspects of fleshy fruit biology, including the genetic, molecular and metabolic mechanisms associated to each of the fruit quality traits. It is also of prime importance to consider the effects of environmental cues, cultural practices and postharvest methods, and to decipher the mechanism by which they impact fruit quality traits. Most of our knowledge of fleshy fruit development, ripening and quality traits comes from work done in a reduced number of species that are not only of economic importance but can also benefit from a number of genetic and genomic tools available to their specific research communities. For instance, working with tomato and grape offers several advantages since the genome sequences of these two fleshy fruit species have been deciphered and a wide range of biological and genetic resources have been developed. Ripening mutants are available for tomato which constitutes the main model system for fruit functional genomics. In addition, tomato is used as a reference species for climacteric fruit which ripening is controlled by the phytohormone ethylene. Likewise, grape is a reference species for non-climacteric fruit even though no single master switches controlling ripening initiation have been uncovered yet. In the last period, the genome sequence of an increased number of fruit crop species became available which creates a suitable situation for research communities around crops to get organized and information to be shared through public repositories. On the other hand, the availability of genome-wide expression profiling technologies has enabled an easier study of global transcriptional changes in fruit species where the sequenced genome is not yet available. In this issue authors will present recent progress including original data as well as authoritative reviews on our understanding of fleshy fruit biology focusing on tomato and grape as model species. |
Contents
Molecular and Metabolic Mechanisms Associated with Fleshy Fruit Quality | 6 |
Use of Natural Diversity and Biotechnology to Increase the Quality and Nutritional Content of Tomato and Grape | 11 |
DNA Methylation and Chromatin Regulation during Fleshy Fruit Development and Ripening | 35 |
Transport and Physiology | 49 |
Identification of Peach NAP Transcription Factor Genes and Characterization of their Expression in Vegetative and Reproductive Organs during Dev... | 66 |
Differential Effects during Pre and Postharvest | 79 |
Structural and Functional Analysis of the GRAS Gene Family in Grapevine Indicates a Role of GRAS Proteins in the Control of Development and Str... | 94 |
New Insights on the Role of Pigments to Monitor Ripening | 116 |
Metabolite Profiling of Italian Tomato Landraces with Different Fruit Types | 233 |
The Relationship between CmADHs and the Diversity of Volatile Organic Compounds of Three Aroma Types of Melon Cucumis melo | 246 |
GeneMetabolite Networks of Volatile Metabolism in Airen and Tempranillo Grape Cultivars Revealed a Distinct Mechanism of Aroma Bouquet Prod... | 258 |
How Does Host Carbon Concentration Modulate the Lifestyle of Postharvest Pathogens during Colonization? | 281 |
InterSpecies Comparative Analysis of Components of Soluble Sugar Concentration in Fleshy Fruits | 287 |
Insights into molecular and metabolic events associated with fruit response to postharvest fungal pathogens | 299 |
FieldGrown Grapevine Berries Use Carotenoids and the Associated Xanthophyll Cycles to Acclimate to UV Exposure Differentially in High and Low ... | 313 |
Grapevine Rootstocks Differentially Affect the Rate of Ripening and Modulate AuxinRelated Genes in Cabernet Sauvignon Berries | 330 |
In silico Transcriptional Regulatory Networks Involved in Tomato Fruit Ripening | 123 |
Nitric Oxide Overproduction in Tomato shr Mutant Shifts Metabolic Profiles and Suppresses Fruit Growth and Ripening | 133 |
On the Developmental and Environmental Regulation of Secondary Metabolism in Vaccinium spp Berries | 151 |
Characterization of Biosynthetic Genes and Regulation by a MYB Transcription Factor | 160 |
Metabolic and Molecular Changes of the Phenylpropanoid Pathway in Tomato Solanum lycopersicum Lines Carrying Different Solanum pennellii W... | 178 |
Exploiting Genomics Resources to Identify Candidate Genes Underlying Antioxidants Content in Tomato Fruit | 193 |
Exploring New Alleles Involved in Tomato Fruit Quality in an Introgression Line Library of Solanum pimpinellifolium | 207 |
Identification of Loci Affecting Accumulation of Secondary Metabolites in Tomato Fruit of a Solanum lycopersicum Solanum chmielewskii Introgr... | 219 |
Kaolin Foliar Application Has a Stimulatory Effect on Phenylpropanoid and Flavonoid Pathways in Grape Berries | 344 |
Plasticity of the Berry Ripening Program in a White Grape Variety | 358 |
RoostocksScionNitrogen Interactions Affect Secondary Metabolism in the Grape Berry | 375 |
The Influence of Genotype and Environment on Small RNA Profiles in Grapevine Berry | 386 |
The Potential of the MAGIC TOM Parental Accessions to Explore the Genetic Variability in Tomato Acclimation to Repeated Cycles of Water Deficit... | 409 |
Identification Expression and IAAAmide Synthetase Activity Analysis of Gretchen Hagen 3 in Papaya Fruit Carica papaya L during Postharvest Proc... | 424 |
Back Cover | 437 |
Common terms and phrases
accumulation acid activity analysis anthocyanin Arabidopsis associated berries Biol biosynthesis calcium carotenoids cell changes characterized clusters collected compared compounds concentration contribute correlation cultivars detected determined developmental effects environment enzyme et al expression Figure flavonoid Food fruit ripening function gene expression genes genetic genome genotypes grape grape berry grapevine growth higher identified important increased indicate interactions introgression involved Italy leaves levels light lines lower mapping mature metabolism metabolites modulated NF NF NF observed pathway performed phenolic phenotypic Plant population positive present processes production profiles protein QTLs reduced region regulation reported represent respectively response ripening role samples sequences showed shown signaling significant similar skin species stages stress sugar suggesting Supplementary Table tissues tomato fruit traits transcription transcription factor treatment values varieties volatile wild