Germplasm Repository, Evaluation and Genetic Improvement of Fruit Trees II

A special issue of Plants (ISSN 2223-7747). This special issue belongs to the section "Plant Genetics, Genomics and Biotechnology".

Deadline for manuscript submissions: closed (20 April 2023) | Viewed by 8051

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Guest Editor
Key Laboratory of South China Agricultural Plant Molecular Analysis and Genetic Improvement, Guangdong Provincial Key Laboratory of Applied Botany, South China Botanical Garden, Chinese Academy of Sciences, Guangzhou 510650, China
Interests: plant ex situ conservation and inventory (project of Ex situ Cultivated Flora of China); Genus Actinidia germplasm repository and evaluation and genetic improvement for new cultivar development; plant conservation genetics
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Dear Colleagues,

Germplasm repositories primarily provide the raw material for plant breeding and crop improvement programs. Hundreds of living germplasm collections of fruit tree crops across the world have played an incredible role in fruit tree breeding and enabled many newly improved cultivars available to the global fruit industry. Germplasm repositories for fruit trees are uniquely constructed as clonal living collections preserved in orchards, vineyards and plantations, nurseries, etc. They include diverse valuable resources such as current commercial cultivars, traditional cultivars, landraces, breeding materials, elite selections and wild relatives. In addition to the preservation and maintenance of well-documented and managed living collections, living fruit tree collections are not only used by fruit breeders; other biologists may have different interests and possibly different requirements. While fruit breeders focus on the commercial traits of immediate perceived value, other biologists may be more interested in studies to better understand the properties and behavior of the plant, as well as its domestication history or evolutionary phylogeny, especially at the genomic level.

One of the prioritized tasks in a germplasm repository of fruit tress is to characterize the genetic diversity and composition of accessions maintained in the repository to capture a genetic and morphological diversity that is as broad as possible; to facilitate the characterization of intra- and interspecific variation; and to understand phylogenetic relationships among all resources including cultivars, varieties, subspecies and species—particularly those between wild relatives. The quantity and quality of data documentation are of crucial importance for any germplasm repository management. Although data documentation has changed over time with initial morphological evaluation, genomic data have been increasingly obtained from a wide range of fruit tree germplasm collections. Genotyping accessions has become routine protocol in fruit tree germplasm collections to verify pedigrees and track a trait of interest in breeding. Nevertheless, genetic information obtained using SSR, SNP, AmpSeq, etc., provides a valuable resource for breeding designs of fruit trees for both traditional breeding and molecular breeding programs—in particular, parentage choice.

The nature of fruit trees as mostly perennial plants also helps other biologists to study and understand many aspects about basic plant biology, such as growth, development, reproduction, biotic and abiotic stress tolerance, metabolite changes, etc., because germplasm repositories of fruit trees are maintained in the same location across multiple years, which offers an important opportunity to study inter-annual variation under common garden conditions. One approach, for example, is to study phenotypic plasticity in response to climatic changes and the adaptive evolution of long-lived plants.

Ultimately, living fruit tree collections are of particular use to fruit tree breeding and genetic improvement for new cultivar development—for example, many new kiwifruit cultivars recently released to the global kiwifruit industry rely heavily on the Chinese National Kiwifruit Germplasm Repository at Wuhan Botanical Garden, Chinese Academy of Sciences. Recently, molecular approaches such as GWAS, QTLs, and other marker-assisted selection techniques have increasingly been used as tools for selecting potential parents from germplasm collections for use in many fruit tree breeding programs to accelerate the breeding process. It is evident that fruit tree improvement is greatly enhanced by standardized and statistically robust procedures for discovering quantitative trait loci (QTL) in germplasm relevant to breeding programs and helps in the validation of important breeding parents (IBPs) by estimating average allelic representation in wild relatives, also demonstrating importance of construction of core germplasm sets in living fruit tree germplasm collections.

Given this context, in this Special Issue, articles (original research papers, perspectives, hypotheses, opinions, reviews, modeling approaches, and methods) that focus on germplasm repository management, evaluation and data documentation, genetics and novel breeding approaches, molecular methods for genetic improvement, gene discovery of traits, and new fruit tree domestication are most welcome.

Prof. Dr. Hongwen Huang
Guest Editor

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Keywords

  • germplasm repository management
  • germplasm evaluation and dada documentation
  • gene discovery of important traits
  • germplasm core sets at genomic level
  • population genomics
  • integration of traditional and genomic breeding
  • climatic changes and adaptive evolution
  • germplasm innovation
  • new fruit tree domestication
  • germplasm networking

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Published Papers (4 papers)

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Research

20 pages, 3177 KiB  
Article
Genome-Wide Identification of Bilberry WRKY Transcription Factors: Go Wild and Duplicate
by Winder Felipez, Jennifer Villavicencio, Valeria Oliveira Nizolli, Camila Pegoraro, Luciano da Maia and Antonio Costa de Oliveira
Plants 2023, 12(18), 3176; https://doi.org/10.3390/plants12183176 - 5 Sep 2023
Cited by 3 | Viewed by 1563
Abstract
WRKY transcription factor genes compose an important family of transcriptional regulators that are present in several plant species. According to previous studies, these genes can also perform important roles in bilberry (Vaccinium myrtillus L.) metabolism, making it essential to deepen our understanding [...] Read more.
WRKY transcription factor genes compose an important family of transcriptional regulators that are present in several plant species. According to previous studies, these genes can also perform important roles in bilberry (Vaccinium myrtillus L.) metabolism, making it essential to deepen our understanding of fruit ripening regulation and anthocyanin biosynthesis. In this context, the detailed characterization of these proteins will provide a comprehensive view of the functional features of VmWRKY genes in different plant organs and in response to different intensities of light. In this study, the investigation of the complete genome of the bilberry identified 76 VmWRKY genes that were evaluated and distributed in all twelve chromosomes. The proteins encoded by these genes were classified into four groups (I, II, III, and IV) based on their conserved domains and zinc finger domain types. Fifteen pairs of VmWRKY genes in segmental duplication and four pairs in tandem duplication were detected. A cis element analysis showed that all promoters of the VmWRKY genes contain at least one potential cis stress-response element. Differential expression analysis of RNA-seq data revealed that VmWRKY genes from bilberry show preferential or specific expression in samples. These findings provide an overview of the functional characterization of these proteins in bilberry. Full article
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11 pages, 3334 KiB  
Article
The Effect of Dwarfing Interstocks on Vegetative Growth, Fruit Quality and Ionome Nutrition of ‘Fuji’ Apple Cultivar ‘Tianhong 2’—A One-Year Study
by Shuang Li, Yanghong Zhang, Haowei Chen, Boyang Li, Bowen Liang and Jizhong Xu
Plants 2023, 12(11), 2158; https://doi.org/10.3390/plants12112158 - 30 May 2023
Cited by 3 | Viewed by 1293
Abstract
Dwarfing interstocks play an essential role in determining the performance of fruit trees. SH40, Jizhen 1, and Jizhen 2 are widely used dwarfing interstocks in Hebei Province, China. This study examined the influence of these three dwarfing interstocks on vegetative growth, fruit quality [...] Read more.
Dwarfing interstocks play an essential role in determining the performance of fruit trees. SH40, Jizhen 1, and Jizhen 2 are widely used dwarfing interstocks in Hebei Province, China. This study examined the influence of these three dwarfing interstocks on vegetative growth, fruit quality and yield, and leaf and fruit macro- (N, P, K, Ca, and Mg) and micro- (Fe, Zn, Cu, Mn, and B) element contents for ‘Tianhong 2’. Five-year-old ‘Fuji’ apple cultivar, ‘Tianhong 2’, on ‘Malus. Robusta’ rootstock, was cultivated with SH40, Jizhen 1, or Jizhen2 dwarfing rootstock as an interstock bridge. Jizhen 1 and 2 had more branches and a higher proportion of short branches than SH40. Jizhen 2 had a higher yield, good fruit quality, and higher leaf macro- (N, P, K, and Ca) and micro-element (Fe, Zn, Cu, Mn, and B) contents; Jizhen 1 had the highest leaf Mg content in the growing period. The fruit N, P, K, Fe, Zn, Cu, Mn, and B contents were higher in Jizhen 2. SH40 had the highest fruit Ca content. There were significant correlations in nutrient elements between leaves and fruit in June and July. Comprehensive analysis showed that Tianhong 2 had moderate tree vigor, high yield, good fruit quality, and high mineral element content in leaves and fruits when Jizhen 2 was used as an interstock. Full article
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11 pages, 2052 KiB  
Article
Breeding and Growth Performance of ‘Ningzhi 4’, a New Blackberry Cultivar with High Yield Potential and Good Quality in China
by Yaqiong Wu, Wenlong Wu, Chunhong Zhang, Lianfei Lyu and Weilin Li
Plants 2023, 12(8), 1661; https://doi.org/10.3390/plants12081661 - 15 Apr 2023
Cited by 1 | Viewed by 1878
Abstract
The thornless blackberry cultivar ‘Ningzhi 4’ was developed by the Institute of Botany, Jiangsu Province and the Chinese Academy of Sciences (Nanjing Botanical Garden Mem. Sun Yat-Sen). The new blackberry cultivar was selected from the ‘Kiowa’ (female parent) and ‘Hull Thornless’ (male parent) [...] Read more.
The thornless blackberry cultivar ‘Ningzhi 4’ was developed by the Institute of Botany, Jiangsu Province and the Chinese Academy of Sciences (Nanjing Botanical Garden Mem. Sun Yat-Sen). The new blackberry cultivar was selected from the ‘Kiowa’ (female parent) and ‘Hull Thornless’ (male parent) F1 hybrid. ‘Ningzhi 4’ had excellent plant characteristics, including thornlessness, semi-erect to erect canes, vigorous growth and good disease resistance. ‘Ningzhi 4’ had large fruit and high yield. In addition, the parents of the superior hybrid plant were further identified by SSR markers, which provided the basis for the fingerprint of the new blackberry cultivar ‘Ningzhi 4’. This is a commercial cultivar to be grown for fruit production for either shipping or local sales. It also has value as a home-garden plant. This unique type of blackberry fruit was a traditional summer fruit. This new cultivar has thornless semi-erect to erect canes and produces high-quality berries with large size, good firmness, excellent flavor, and potential for shipping and postharvest storage. The new blackberry cultivar ‘Ningzhi 4’ is adapted to all areas of southern China and is expected to replace or complement ‘Kiowa’, ‘Hull Thornless’, ‘Chester Thornless’ and ‘Triple Crown’. A local cultivar patent has been approved by the Jiangsu Variety Approval Committee as ‘Rubus spp. Ningzhi 4′ in 2020 (S-SV-RS-014-2020). In the future, ‘Ningzhi 4’ could be promoted as an advantageous thornless blackberry cultivar in the main production regions of China. Full article
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15 pages, 2664 KiB  
Article
Sweet Cherry Diversity and Relationships in Modern and Local Varieties Based on SNP Markers
by Marino Palasciano, Diana L. Zuluaga, Domenico Cerbino, Emanuela Blanco, Gaetano Aufiero, Nunzio D’Agostino and Gabriella Sonnante
Plants 2023, 12(1), 136; https://doi.org/10.3390/plants12010136 - 27 Dec 2022
Cited by 7 | Viewed by 2688
Abstract
The sweet cherry is an important fruit species that is widespread globally. In addition to the well-known traditional and modern varieties, a myriad of landraces is present in Europe, as well as in southern Italy. This study aims to evaluate the population structure, [...] Read more.
The sweet cherry is an important fruit species that is widespread globally. In addition to the well-known traditional and modern varieties, a myriad of landraces is present in Europe, as well as in southern Italy. This study aims to evaluate the population structure, genetic relationships, and cases of duplicate samples in a collection of 143 accessions using GBS-derived SNP markers. The genetic material under investigation includes modern commercial varieties, ancient European and American varieties, landraces, and individuals retrieved from small orchards. Some of the known varieties were genetically analyzed here for the first time. In addition, several genotypes were collected from the Basilicata region (southern Italy), an area largely unexplored for sweet cherry genetic resources. The relationships among genotypes were assessed using four different methods: allele frequency and ancestry estimation, principal component analysis, Neighbor-Joining tree, and identity-by-state estimation. The analyses returned quite congruent results and highlighted the presence of four main genetic groups, namely: (i) American varieties, (ii) the ‘Germersdorfer-Ferrovia’ cluster, (iii) the ‘Burlat’ group, and (iv) the group of Italian landraces. The main drivers of clustering were ancestry, geographical distribution, and some important traits such as self-compatibility. The sweet cherries from Basilicata, herewith examined for the first time, were mostly distributed within the group of Italian landraces, being particularly linked to the autochthonous varieties of the Campania region. However, some genotypes were outside this group, thus suggesting the introduction of genetic material from other Italian regions or from European countries. The considerable amount of American and European modern varieties analyzed are genetically very closely related, suggesting a reduced genetic basis. In addition, we highlighted the discriminating ability of SNP markers to distinguish between an original variety and its mutant. Overall, our results may be useful in defining conservation strategies for sweet cherry germplasm and developing future breeding programs to enlarge the genetic basis of commercial varieties. Full article
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