Your search keyword '"Vining, Kelly J."' showing total 9 results

1. Mentha L. and Pycnanthemum L. Germplasm at the US National Clonal Germplasm Repository in Corvallis, Oregon

Author

Hummer, Kim, Bassil, Nahla, Vining, Kelly J., and Máthé, Ákos, Series Editor

Published

2020

2. Genetic diversity survey of Mentha aquatica L. and Mentha suaveolens Ehrh., mint crop ancestors

Author

Vining, Kelly J., Pandelova, Iovanna, Hummer, Kim, Bassil, Nahla, Contreras, Ryan, Neill, Kristin, Chen, Hsuan, Parrish, Amber N., and Lange, Bernd Markus

Published

2019

3. Biochemical basis for the formation of organ-specific volatile blends in mint.

Author

Lange, B. Markus, Srividya, Narayanan, Lange, Iris, Parrish, Amber N., Benzenberg, Lukas R., Pandelova, Iovanna, Vining, Kelly J., and Wüst, Matthias

Subjects

MONOTERPENES, MINTS (Plants), VERTICILLIUM wilt diseases, SPEARMINT, RECOMBINANT proteins, ESSENTIAL oils, LAMIACEAE

Abstract

Above-ground material of members of the mint family is commercially distilled to extract essential oils, which are then formulated into a myriad of consumer products. Most of the research aimed at characterizing the processes involved in the formation of terpenoid oil constituents has focused on leaves. We now demonstrate, by investigating three mint species, peppermint (Mentha×piperita L.), spearmint (Mentha spicata L.) and horsemint (Mentha longifolia (L.) Huds.; accessions CMEN 585 and CMEN 584), that other organs - namely stems, rhizomes and roots - also emit volatiles and that the terpenoid volatile composition of these organs can vary substantially from that of leaves, supporting the notion that substantial, currently underappreciated, chemical diversity exists. Differences in volatile quantities released by plants whose roots had been dipped in a Verticillium dahliae-spore suspension (experimental) or dipped in water (controls) were evident: increases of some volatiles in the root headspace of mint species that are susceptible to Verticillium wilt disease (peppermint and M. longifolia CMEN 584) were detected, while the quantities of certain volatiles decreased in rhizomes of species that show resistance to the disease (spearmint and M. longifolia CMEN 585). To address the genetic and biochemical basis underlying chemical diversity, we took advantage of the newly sequenced M. longifolia CMEN 585 genome to identify candidate genes putatively coding for monoterpene synthases (MTSs), the enzymes that catalyze the first committed step in the biosynthesis of monoterpenoid volatiles. The functions of these genes were established by heterologous expression in Escherichia coli, purification of the corresponding recombinant proteins, and enzyme assays, thereby establishing the existence of MTSs with activities to convert a common substrate, geranyl diphosphate, to (+)-α-terpineol, 1,8-cineole, γ-terpinene, and (-)-bornyl diphosphate, but were not active with other potential substrates. In conjunction with previously described MTSs that catalyze the formation of (-)-β-pinene and (-)-limonene, the product profiles of the MTSs identified here can explain the generation of all major monoterpene skeletons represented in the volatiles released by different mint organs. [ABSTRACT FROM AUTHOR]

Published

2023

4. Chromosome-level genome assembly of Mentha longifolia L. reveals gene organization underlying disease resistance and essential oil traits.

Author

Vining, Kelly J., Pandelova, Iovanna, Lange, Iris, Parrish, Amber N., Lefors, Andrew, Kronmiller, Brent, Liachko, Ivan, Kronenberg, Zev, Srividya, Narayanan, and Lange, B. Markus

Subjects

*SPEARMINT, *ESSENTIAL oils, *NATURAL immunity, *VERTICILLIUM wilt diseases, *MINTS (Plants), *DOCUMENT clustering

Abstract

Mentha longifolia (L.) Huds., a wild, diploid mint species, has been developed as a model for mint genetic and genomic research to aid breeding efforts that target Verticillium wilt disease resistance and essential oil monoterpene composition. Here, we present a nearcomplete, chromosome-scale mint genome assembly for M. longifolia USDA accession CMEN 585. This new assembly is an update of a previously published genome draft, with dramatic improvements. A total of 42,107 protein-coding genes were annotated and placed on 12 chromosomal scaffolds. One hundred fifty-three genes contained conserved sequence domains consistent with nucleotide binding siteleucine-rich-repeat plant disease resistance genes. Homologs of genes implicated in Verticillium wilt resistance in other plant species were also identified. Multiple paralogs of genes putatively involved in p-menthane monoterpenoid biosynthesis were identified and several cases of gene clustering documented. Heterologous expression of candidate genes, purification of recombinant target proteins, and subsequent enzyme assays allowed us to identify the genes underlying the pathway that leads to the most abundant monoterpenoid volatiles. The bioinformatic and functional analyses presented here are laying the groundwork for using marker-assisted selection in improving disease resistance and essential oil traits in mints. [ABSTRACT FROM AUTHOR]

Published

2022

5. Crop Wild Relatives as Germplasm Resource for Cultivar Improvement in Mint (Mentha L.).

Author

Vining, Kelly J., Hummer, Kim E., Bassil, Nahla V., Lange, B. Markus, Khoury, Colin K., and Carver, Dan

Subjects

AROMATIC plants, GERMPLASM, MINTS (Plants), CROPS, PLANT germplasm, HERBS

Abstract

Mentha is a strongly scented herb of the Lamiaceae (formerly Labiatae) and includes about 30 species and hybrid species that are distributed or introduced throughout the globe. These fragrant plants have been selected throughout millennia for use by humans as herbs, spices, and pharmaceutical needs. The distilling of essential oils from mint began in Japan and England but has become a significant industrial product for the US, China, India, and other countries. The US Department of Agriculture (USDA), Agricultural Research Service, National Clonal Germplasm Repository (NCGR) maintains a mint genebank in Corvallis, Oregon. This facility preserves and distributes about 450 clones representing 34 taxa, hybrid species, advanced breeder selections, and F1 hybrids. Mint crop wild relatives are included in this unique resource. The majority of mint accessions and hybrids in this collection were initially donated in the 1970s by the A.M. Todd Company, located in Kalamazoo, Michigan. Other representatives of diverse mint taxa and crop wild relatives have since been obtained from collaborators in Australia, New Zealand, Europe, and Vietnam. These mints have been evaluated for cytology, oil components, verticillium wilt resistance, and key morphological characters. Pressed voucher specimens have been prepared for morphological identity verification. An initial set of microsatellite markers has been developed to determine clonal identity and assess genetic diversity. Plant breeders at private and public institutions are using molecular analysis to determine identity and diversity of the USDA mint collection. Evaluation and characterization includes essential oil content, disease resistance, male sterility, and other traits for potential breeding use. These accessions can be a source for parental genes for enhancement efforts to produce hybrids, or for breeding new cultivars for agricultural production. Propagules of Mentha are available for distribution to international researchers as stem cuttings, rhizome cuttings, or seed, which can be requested through the GRIN-Global database of the US National Plant Germplasm System, subject to international treaty and quarantine regulations. [ABSTRACT FROM AUTHOR]

Published

2020

6. Draft Genome Sequence of Mentha longifolia and Development of Resources for Mint Cultivar Improvement.

Author

Vining, Kelly J., Johnson, Sean R., Ahkami, Amirhossein, Lange, Iris, Parrish, Amber N., Trapp, Susan C., Croteau, Rodney B., Straub, Shannon C.K., Pandelova, Iovanna, and Lange, B. Markus

Abstract

The genus Mentha encompasses mint species cultivated for their essential oils, which are formulated into a vast array of consumer products. Desirable oil characteristics and resistance to the fungal disease Verticillium wilt are top priorities for the mint industry. However, cultivated mints have complex polyploid genomes and are sterile. Breeding efforts, therefore, require the development of genomic resources for fertile mint species. Here, we present draft de novo genome and plastome assemblies for a wilt-resistant South African accession of Mentha longifolia (L.) Huds., a diploid species ancestral to cultivated peppermint and spearmint. The 353 Mb genome contains 35 597 predicted protein-coding genes, including 292 disease resistance gene homologs, and nine genes determining essential oil characteristics. A genetic linkage map ordered 1397 genome scaffolds on 12 pseudochromosomes. More than two million simple sequence repeats were identified, which will facilitate molecular marker development. The M. longifolia genome is a valuable resource for both metabolic engineering and molecular breeding. This is exemplified by employing the genome sequence to clone and functionally characterize the promoters in a peppermint cultivar, and demonstrating the utility of a glandular trichome-specific promoter to increase expression of a biosynthetic gene, thereby modulating essential oil composition. [ABSTRACT FROM AUTHOR]

Published

2017

7. Dynamic Tissue—Specific Transcriptome Changes in Response to Verticillium dahliae in Wild Mint Species Mentha longifolia.

Author

Vining, Kelly J. and Pandelova, Iovanna

Subjects

VERTICILLIUM dahliae, SPEARMINT, FUNGAL genetics, SPECIES, TRANSCRIPTOMES, GENE expression

Abstract

Mentha longifolia is a wild mint species being used as a model to study the genetics of resistance to the fungal wilt pathogen Verticillium dahliae. We used high-throughput Illumina sequencing to study gene expression in response to V. dahliae inoculation in two M. longifolia USDA accessions with contrasting phenotypes: wilt-resistant CMEN 585 and wilt-susceptible CMEN 584. Roots and stems were sampled at two early post-inoculation time points, four hours and twenty-four hours, and again at ten days and twenty days post-inoculation. Overall, many more genes were differentially-regulated in wilt-resistant CMEN 585 than in wilt-susceptible CMEN 584. The greatest numbers of differentially expressed genes were found in the roots of CMEN 585 at the early time points. Specific genes exhibiting early, strong upregulation in roots of CMEN 585 but not in CMEN 584 included homologs of known plant defense response genes as well as genes involved in monoterpene biosynthesis. These genes were also upregulated in stems at the later time points. This study provides a comprehensive view of transcription reprogramming in Verticillium wilt-resistant mint, which will be the basis for further study and for molecular marker development. [ABSTRACT FROM AUTHOR]

Published

2022

8. A first look at the genome structure of hexaploid "Mitcham" peppermint (Mentha × piperita L.).

Author

Talbot, Samuel C, Pandelova, Iovanna, Lange, Bernd Markus, and Vining, Kelly J

Subjects

*MINTS (Plants), *ESSENTIAL oils, *PEPPERMINT, *VERTICILLIUM dahliae, *MYCOSES

Abstract

Peppermint, Mentha × piperita L. is a hexaploid (2 n = 6 x = 72) and the predominant cultivar of commercial mint oil production in the US. This cultivar is threatened because of high susceptibility to the fungal disease verticillium wilt, caused by Verticillium dahliae. This report details the first draft polyploid chromosome-level genome assembly for this mint species. The "Mitcham" genome resource will broaden comparative studies of disease resistance, essential oil biosynthesis, and hybridization events within the genus Mentha. It will also be a valuable contribution to the body of phylogenetic studies involving Mentha and other genera that contain species with varying ploidy levels. [ABSTRACT FROM AUTHOR]

Published

2024

9. Identification of Resistance Gene Analogs and Verticillium Wilt Resistance-like Sequences in Mentha longifolia.

Author

Vining, Kelly J., Zhang, Q., Smith, C.A., and Davis, T. M.

Subjects

*POLYMERASE chain reaction, *INTERLEUKINS, *GROWTH factors, *SPEARMINT, *MINTS (Plants)

Abstract

Resistance gene analog (RGA) sequences were obtained from four Mentha longifolia (L.) Huds. accessions using degenerate polymerase chain reaction (PCR) primers targeting the conserved nucleotide binding site domain found in many plant disease resistance genes. Seven distinct RGA families were identified. All M. longifolia RGAs showed similarity to sequences of the non-toll-interleukin 1 receptor R gene class. In addition, degenerate PCR primers based on the tomato (Solanum lycopersicum L.) verticillium wilt resistance (Ve) genes were used to PCR-amplify a 445-base pair (bp) Ve-like sequence from M. longifolia that had ≈57% predicted amino acid identity with Ve. Mint-specific primers based on the original mint Ve sequence were used to obtain mint-specific Ve sequences from four M. longifolia accessions and from peppermint (Mentha xpiperita L.) cultivar ‘Black Mitcham’ that had 95% to 100% predicted amino acid identity to the original mint Ve sequence. Inverse PCR was then used to obtain flanking mint Ve sequence from one M. longifolia accession extending the mint Ve sequence to 1077 bp. This is the first report of RGA sequences in the Lamiaceae and the first report of Ve-like sequences obtained with degenerate PCR primers. [ABSTRACT FROM AUTHOR]

Published

2007