Your search keyword '"Sherman, Amir"' showing total 7 results

1. Genetic diversity of avocado (Persea americana Mill.) germplasm using pooled sequencing

Author

Rubinstein, Mor, Eshed, Ravit, Rozen, Ada, Zviran, Tali, Kuhn, David N., Irihimovitch, Vered, Sherman, Amir, and Ophir, Ron

Published

2019

2. The 'Tommy Atkins' mango genome reveals candidate genes for fruit quality.

Author

Bally, Ian S. E., Bombarely, Aureliano, Chambers, Alan H., Cohen, Yuval, Dillon, Natalie L., Innes, David J., Islas-Osuna, María A., Kuhn, David N., Mueller, Lukas A., Ophir, Ron, Rambani, Aditi, Sherman, Amir, and Yan, Haidong

Subjects

MANGO, GENES, FRUIT quality, TROPICAL fruit, CASHEW tree, TROPICAL crops

Abstract

Background: Mango, Mangifera indica L., an important tropical fruit crop, is grown for its sweet and aromatic fruits. Past improvement of this species has predominantly relied on chance seedlings derived from over 1000 cultivars in the Indian sub-continent with a large variation for fruit size, yield, biotic and abiotic stress resistance, and fruit quality among other traits. Historically, mango has been an orphan crop with very limited molecular information. Only recently have molecular and genomics-based analyses enabled the creation of linkage maps, transcriptomes, and diversity analysis of large collections. Additionally, the combined analysis of genomic and phenotypic information is poised to improve mango breeding efficiency. Results: This study sequenced, de novo assembled, analyzed, and annotated the genome of the monoembryonic mango cultivar 'Tommy Atkins'. The draft genome sequence was generated using NRGene de-novo Magic on high molecular weight DNA of 'Tommy Atkins', supplemented by 10X Genomics long read sequencing to improve the initial assembly. A hybrid population between 'Tommy Atkins' x 'Kensington Pride' was used to generate phased haplotype chromosomes and a highly resolved phased SNP map. The final 'Tommy Atkins' genome assembly was a consensus sequence that included 20 pseudomolecules representing the 20 chromosomes of mango and included ~ 86% of the ~ 439 Mb haploid mango genome. Skim sequencing identified ~ 3.3 M SNPs using the 'Tommy Atkins' x 'Kensington Pride' mapping population. Repeat masking identified 26,616 genes with a median length of 3348 bp. A whole genome duplication analysis revealed an ancestral 65 MYA polyploidization event shared with Anacardium occidentale. Two regions, one on LG4 and one on LG7 containing 28 candidate genes, were associated with the commercially important fruit size characteristic in the mapping population. Conclusions: The availability of the complete 'Tommy Atkins' mango genome will aid global initiatives to study mango genetics. [ABSTRACT FROM AUTHOR]

Published

2021

3. Fungal and host transcriptome analysis of pH-regulated genes during colonization of apple fruits by Penicillium expansum.

Author

Barad, Shiri, Sela, Noa, Kumar, Dilip, Kumar-Dubey, Amit, Glam-Matana, Nofar, Sherman, Amir, and Prusky, Dov

Subjects

GENETIC transcription, FUNGAL genes, APPLE blue mold, APPLE genetics, GLUCONIC acid

Abstract

Background: Penicillium expansum is a destructive phytopathogen that causes decay in deciduous fruits during postharvest handling and storage. During colonization the fungus secretes D-gluconic acid (GLA), which modulates environmental pH and regulates mycotoxin accumulation in colonized tissue. Till now no transcriptomic analysis has addressed the specific contribution of the pathogen's pH regulation to the P. expansum colonization process. For this purpose total RNA from the leading edge of P. expansum-colonized apple tissue of cv. 'Golden Delicious' and from fungal cultures grown under pH 4 or 7 were sequenced and their gene expression patterns were compared. Results: We present a large-scale analysis of the transcriptome data of P. expansum and apple response to fungal colonization. The fungal analysis revealed nine different clusters of gene expression patterns that were divided among three major groups in which the colonized tissue showed, respectively: (i) differing transcript expression patterns between mycelial growth at pH 4 and pH 7; (ii) similar transcript expression patterns of mycelial growth at pH 4; and (iii) similar transcript expression patterns of mycelial growth at pH 7. Each group was functionally characterized in order to decipher genes that are important for pH regulation and also for colonization of apple fruits by Penicillium. Furthermore, comparison of gene expression of healthy apple tissue with that of colonized tissue showed that differentially expressed genes revealed up-regulation of the jasmonic acid and mevalonate pathways, and also down-regulation of the glycogen and starch biosynthesis pathways. Conclusions: Overall, we identified important genes and functionalities of P. expansum that were controlled by the environmental pH. Differential expression patterns of genes belonging to the same gene family suggest that genes were selectively activated according to their optimal environmental conditions (pH, in vitro or in vivo) to enable the fungus to cope with varying conditions and to make optimal use of available enzymes. Comparison between the activation of the colonized host's gene responses by alkalizing Colletotrichum gloeosporioides and acidifying P. expansum pathogens indicated similar gene response patterns, but stronger responses to P. expansum, suggesting the importance of acidification by P. expansum as a factor in its increased aggressiveness. [ABSTRACT FROM AUTHOR]

Published

2016

4. Mango (Mangifera indica L.) germplasm diversity based on single nucleotide polymorphisms derived from the transcriptome.

Author

Sherman, Amir, Rubinstein, Mor, Eshed, Ravit, Benita, Miri, Ish-Shalom, Mazal, Sharabi-Schwager, Michal, Rozen, Ada, Saada, David, Cohen, Yuval, and Ophir, Ron

Subjects

*PLANT germplasm, *MANGO, *PLANT breeding, *MANGIFERA, *SINGLE nucleotide polymorphisms, *CULTIVARS, *GENETICS

Abstract

Background: Germplasm collections are an important source for plant breeding, especially in fruit trees which have a long duration of juvenile period. Thus, efforts have been made to study the diversity of fruit tree collections. Even though mango is an economically important crop, most of the studies on diversity in mango collections have been conducted with a small number of genetic markers. Results: We describe a de novo transcriptome assembly from mango cultivar 'Keitt'. Variation discovery was performed using Illumina resequencing of 'Keitt' and 'Tommy Atkins' cultivars identified 332,016 single-nucleotide polymorphisms (SNPs) and 1903 simple-sequence repeats (SSRs). Most of the SSRs (70.1 %) were of trinucleotide with the preponderance of motif (GGA/AAG)n and only 23.5 % were di-nucleotide SSRs with the mostly of (AT/AT)n motif. Further investigation of the diversity in the Israeli mango collection was performed based on a subset of 293 SNPs. Those markers have divided the Israeli mango collection into two major groups: one group included mostly mango accessions from Southeast Asia (Malaysia, Thailand, Indonesia) and India and the other with mainly of Floridian and Israeli mango cultivars. The latter group was more polymorphic (FS = -0.1 on the average) and was more of an admixture than the former group. A slight population differentiation was detected (FST = 0.03), suggesting that if the mango accessions of the western world apparently was originated from Southeast Asia, as has been previously suggested, the duration of cultivation was not long enough to develop a distinct genetic background. Conclusions: Whole-transcriptome reconstruction was used to significantly broaden the mango's genetic variation resources, i.e., SNPs and SSRs. The set of SNP markers described in this study is novel. A subset of SNPs was sampled to explore the Israeli mango collection and most of them were polymorphic in many mango accessions. Therefore, we believe that these SNPs will be valuable as they recapitulate and strengthen the history of mango diversity. [ABSTRACT FROM AUTHOR]

Published

2015

5. Integrated transcriptome catalogue and organspecific profiling of gene expression in fertile garlic (Allium sativum L.).

Author

Kamenetsky, Rina, Faigenboim, Adi, Mayer, Einat Shemesh, Michael, Tomer Ben, Gershberg, Chen, Kimhi, Sagie, Esquira, Itzhak, Shalom, Sarit Rohkin, Eshel, Dani, Rabinowitch, Haim D., and Sherman, Amir

Subjects

GARLIC, GENETIC regulation, GENE expression, MOLECULAR genetics, PLANT reproduction

Abstract

Background Garlic is cultivated and consumed worldwide as a popular condiment and green vegetable with medicinal and neutraceutical properties. Garlic cultivars do not produce seeds, and therefore, this plant has not been the subject of either classical breeding or genetic studies. However, recent achievements in fertility restoration in a number of genotypes have led to flowering and seed production, thus enabling genetic studies and breeding in garlic. Results A transcriptome catalogue of fertile garlic was produced from multiplexed gene libraries, using RNA collected from various plant organs, including inflorescences and flowers. Over 32 million 250-bp paired-end reads were assembled into an extensive transcriptome of 240,000 contigs. An abundant transcriptome assembled separately from 102,000 highly expressed contigs was annotated and analyzed for gene ontology and metabolic pathways. Organ-specific analysis showed significant variation of gene expression between plant organs, with the highest number of specific reads in inflorescences and flowers. Analysis of the enriched biological processes and molecular functions revealed characteristic patterns for stress response, flower development and photosynthetic activity. Orthologues of key flowering genes were differentially expressed, not only in reproductive tissues, but also in leaves and bulbs, suggesting their role in flower-signal transduction and the bulbing process. More than 100 variants and isoforms of enzymes involved in organosulfur metabolism were differentially expressed and had organ-specific patterns. In addition to plant genes, viral RNA of at least four garlic viruses was detected, mostly in the roots and cloves, whereas only 1- 4% of the reads were found in the foliage leaves. Conclusions The de novo transcriptome of fertile garlic represents a new resource for research and breeding of this important crop, as well as for the development of effective molecular markers for useful traits, including fertility and seed production, resistance to pests and neutraceutical characteristics. [ABSTRACT FROM AUTHOR]

Published

2015

6. A BAC/BIBAC-based physical map of chickpea, Cicer arietinum L.

Author

Xiaojun Zhang, Scheuring, Chantel F., Meiping Zhang, Dong, Jennifer J., Yang Zhang, Huang, James J., Mi-Kyung Lee, Abbo, Shahal, Sherman, Amir, Shtienberg, Dani, Weidong Chen, Muehlbauer, Fred, and Hong-Bin Zhang

Subjects

CHICKPEA, CICER, PLANT gene mapping, LEGUMES, NUCLEOTIDE sequence

Abstract

Background: Chickpea (Cicer arietinum L.) is the third most important pulse crop worldwide. Despite its importance, relatively little is known about its genome. The availability of a genome-wide physical map allows rapid fine mapping of QTL, development of high-density genome maps, and sequencing of the entire genome. However, no such a physical map has been developed in chickpea. Results: We present a genome-wide, BAC/BIBAC-based physical map of chickpea developed by fingerprint analysis. Four chickpea BAC and BIBAC libraries, two of which were constructed in this study, were used. A total of 67,584 clones were fingerprinted, and 64,211 (∼11.7 x) of the fingerprints validated and used in the physical map assembly. The physical map consists of 1,945 BAC/BIBAC contigs, with each containing an average of 28.3 clones and having an average physical length of 559 kb. The contigs collectively span approximately 1,088 Mb. By using the physical map, we identified the BAC/BIBAC contigs containing or closely linked to QTL4.1 for resistance to Didymella rabiei (RDR) and QTL8 for days to first flower (DTF), thus further verifying the physical map and confirming its utility in fine mapping and cloning of QTL. Conclusion: The physical map represents the first genome-wide, BAC/BIBAC-based physical map of chickpea. This map, along with other genomic resources previously developed in the species and the genome sequences of related species (soybean, Medicago and Lotus), will provide a foundation necessary for many areas of advanced genomics research in chickpea and other legume species. The inclusion of transformation-ready BIBACs in the map greatly facilitates its utility in functional analysis of the legume genomes. [ABSTRACT FROM AUTHOR]

Published

2010

7. High-throughput marker discovery in melon using a self-designed oligo microarray.

Author

Ophir, Ron, Eshed, Ravit, Harel-Beja, Rotem, Tzuri, Galil, Portnoy, Vitaly, Burger, Yoseph, Uliel, Shai, Katzir, Nurit, and Sherman, Amir

Subjects

GENE mapping, BIOMARKERS, IN situ hybridization, GENETIC polymorphisms, BIOLOGICAL variation

Abstract

Background: Genetic maps constitute the basis of breeding programs for many agricultural organisms. The creation of these maps is dependent on marker discovery. Melon, among other crops, is still lagging in genomic resources, limiting the ability to discover new markers in a high-throughput fashion. One of the methods used to search for molecular markers is DNA hybridization to microarrays. Microarray hybridization of DNA from different accessions can reveal differences between them--single-feature polymorphisms (SFPs). These SFPs can be used as markers for breeding purposes, or they can be converted to conventional markers by sequencing. This method has been utilized in a few different plants to discover genetic variation, using Affymetrix arrays that exist for only a few organisms. We applied this approach with some modifications for marker discovery in melon. Results: Using a custom-designed oligonucleotide microarray based on a partial EST collection of melon, we discovered 6184 putative SFPs between the parents of our mapping population. Validation by sequencing of 245 SFPs from the two parents showed a sensitivity of around 79%. Most SFPs (81%) contained single-nucleotide polymorphisms. Testing the SFPs on another mapping population of melon confirmed that many of them are conserved. Conclusion: Thousands of new SFPs that can be used for genetic mapping and molecular-assisted breeding in melon were discovered using a custom-designed oligo microarray. A portion of these SFPs are conserved and can be used in different breeding populations. Although improvement of the discovery rate is still needed, this approach is applicable to many agricultural systems with limited genomic resources. [ABSTRACT FROM AUTHOR]

Published

2010