Your search keyword '"Sharma, Saloni"' showing total 11 results

1. Genome–Transcriptome Transition Approaches to Characterize Anthocyanin Biosynthesis Pathway Genes in Blue, Black and Purple Wheat.

Author

Kapoor, Payal, Sharma, Saloni, Tiwari, Apoorv, Kaur, Satveer, Kumari, Anita, Sonah, Humira, Goyal, Ajay, Krishania, Meena, and Garg, Monika

Subjects

*ANTHOCYANINS, *BIOSYNTHESIS, *WHEAT seeds, *GENE expression, *GENES, *RNA sequencing, *WHEAT

Abstract

Colored wheat has gained enormous attention from the scientific community, but the information available on the anthocyanin biosynthetic genes is very minimal. The study involved their genome-wide identification, in silico characterization and differential expression analysis among purple, blue, black and white wheat lines. The recently released wheat genome mining putatively identified eight structural genes in the anthocyanin biosynthesis pathway with a total of 1194 isoforms. Genes showed distinct exon architecture, domain profile, regulatory elements, chromosome emplacement, tissue localization, phylogeny and synteny, indicative of their unique function. RNA sequencing of developing seeds from colored (black, blue and purple) and white wheats identified differential expressions in 97 isoforms. The F3H on group two chromosomes and F3′5′H on 1D chromosomes could be significant influencers in purple and blue color development, respectively. Apart from a role in anthocyanin biosynthesis, these putative structural genes also played an important role in light, drought, low temperature and other defense responses. The information can assist in targeted anthocyanin production in the wheat seed endosperm. [ABSTRACT FROM AUTHOR]

Published

2023

2. Integrated transcriptional and metabolomics signature pattern of pigmented wheat to insight the seed pigmentation and other associated features.

Author

Sharma, Saloni, Kumar, Ashish, Singh, Dalwinder, Kumari, Anita, Kapoor, Payal, Kaur, Satveer, Shreon, Bhawna, and Garg, Monika

Subjects

*WHEAT seeds, *WHEAT, *GENE expression profiling, *ANIMAL coloration, *GENETIC recombination, *METABOLOMICS, *REGULATOR genes, *STARCH metabolism

Abstract

Anthocyanin biosynthesis in plants is complex, especially in a polyploid monocot wheat plant. Using whole-genome sequencing, transcriptomics, and LC-MS/MS, we investigated anthocyanin pigmentation patterns in (black, blue, and purple) colored wheat seeds. According to differential gene expression profiling, 2AS-MYC, 7DL-MYB, and WD40 regulatory genes control purple pericarp coloration, 4DL-MYC, 2AS-MYC, 7DL-MYB, WD40 control blue aleurone coloration, and 4DL-MYC, 7DL-MYB, WD40 controls black aleurone color. We hypothesized that at least one MYC and MYB isoform is sufficient to regulate the anthocyanin synthesis in pericarp or aleurone. Transcriptomics and metabolomics revealed that the purple pericarp trait is associated with acylated anthocyanins compared to blue aleurone. Based upon the reduced expressions of the genes belonging to the 4D, SSR molecular marker mapping, variant calling using genome sequencing, and IGV browser gene structure visualization, it was inferred that the advanced black and blue wheat lines were substitution lines (4E{4D}), with very small recombinations. Pericarp anthocyanin pigmentation is controlled by a mutation in chromosome 2AS of purple wheat, and environmental variations influence pigmented pericarp trait. The expression patterns of anthocyanin structural and other genes varied in different colored wheat, corroborating differences in agronomical metrics. Ovate seed shape trait in black and blue wheat dragged with 4E chromosome. [Display omitted] • One isoform of MYB and MYC, are adequate for anthocyanin modulation in the pericarp and aleurone of wheat seed through ternary complex. • Transcriptomics and metabolomics revealed that acylated anthocyanins are more accumulated in pigmented pericarp wheat as compared to pigmented aleurone. • Pigmented pericarp trait is more responsive to environmental variations, specifically UV irradiation and temperature stress. • Advanced black and blue wheat lines were substitution line (4E{4D}), with very small recombinations in distal part of chromosome. • Black and blue wheat 4E substituted genes adversely affect carbohydrate and starch metabolism, limiting grain size and yield. [ABSTRACT FROM AUTHOR]

Published

2022

3. Gene Expression and Proteomics Studies Suggest an Involvement of Multiple Pathways Under Day and Day–Night Combined Heat Stresses During Grain Filling in Wheat.

Author

Chunduri, Venkatesh, Kaur, Amandeep, Kaur, Shubhpreet, Kumar, Aman, Sharma, Saloni, Sharma, Natasha, Singh, Pargat, Kapoor, Payal, Kaur, Satveer, Kumari, Anita, Roy, Joy, Kaur, Jaspreet, and Garg, Monika

Subjects

PROTEIN expression, PROTEOMICS, GENE expression, POLYACRYLAMIDE gel electrophoresis, WHEAT, TIME-of-flight spectroscopy

Abstract

Recent weather fluctuations imposing heat stress at the time of wheat grain filling cause frequent losses in grain yield and quality. Field-based studies for understanding the effect of terminal heat stress on wheat are complicated by the effect of multiple confounding variables. In the present study, the effect of day and day–night combined heat stresses during the grain-filling stage was studied using gene expression and proteomics approaches. The gene expression analysis was performed by using real-time quantitative PCR (RT-qPCR). The expression of genes related to the starch biosynthetic pathway, starch transporters, transcription factors, and stress-responsive and storage proteins, at four different grain developmental stages, indicated the involvement of multiple pathways. Under the controlled conditions, their expression was observed until 28 days after anthesis (DAA). However, under the day stress and day–night stress, the expression of genes was initiated earlier and was observed until 14 DAA and 7 DAA, respectively. The protein profiles generated using two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) and matrix-assisted laser desorption/ionization time-of-flight mass spectroscopy (MALDI-TOF MS/MS) showed a differential expression of the proteins belonging to multiple pathways that included the upregulation of proteins related to the translation, gliadins, and low-molecular-weight (LMW) glutenins and the downregulation of proteins related to the glycolysis, photosynthesis, defense, and high-molecular-weight (HMW) glutenins. Overall, the defense response to the day heat stress caused early gene expression and day–night heat stress caused suppression of gene expression by activating multiple pathways, which ultimately led to the reduction in grain-filling duration, grain weight, yield, and processing quality. [ABSTRACT FROM AUTHOR]

Published

2021

4. Potential of Aegilops sp. for Improvement of Grain Processing and Nutritional Quality in Wheat (Triticum aestivum).

Author

Kumar, Aman, Kapoor, Payal, Chunduri, Venkatesh, Sharma, Saloni, and Garg, Monika

Subjects

WHEAT, GRAIN, WHEAT quality

Abstract

Wheat is one of the most important staple crops in the world and good source of calories and nutrition. Its flour and dough have unique physical properties and can be processed to make unique products like bread, cakes, biscuits, pasta, noodles etc., which is not possible from other staple crops. Due to domestication, the genetic variability of the genes coding for different economically important traits in wheat is narrow. This genetic variability can be increased by utilizing its wild relatives. Its closest relative, genus Aegilops can be an important source of new alleles. Aegilops has played a very important role in evolution of tetraploid and hexaploid wheat. It consists of 22 species with C, D, M, N, S, T and U genomes with high allelic diversity relative to wheat. Its utilization for wheat improvement for various abiotic and biotic stresses has been reported by various scientific publications. Here in, for the first time, we review the potential of Aegilops for improvement of processing and nutritional traits in wheat. Among processing quality related gluten proteins; high molecular weight glutenins (HMW GS), being easiest to study have been explored in highest number of accessions or lines i.e., 681 belonging to 13 species and selected ones like Ae. searsii , Ae. geniculata and Ae. longissima have been linked with improved bread making quality of wheat. Gliadins and low molecular weight glutenins (LMW GS) have also been extensively explored for wheat improvement and Ae. umbellulata specific LMW GS have been linked with wheat bread making quality improvement. Aegilops has been explored for seed texture diversity and proteins like puroindolins (Pin) and grain softness proteins (GSP). For nutrition quality improvement, it has been screened for essential micronutrients like Fe, Zn, phytochemicals like carotenoids and dietary fibers like arabinoxylan and β-glucan. Ae. kotschyi and Ae. biuncialis transfer in wheat have been associated with higher Fe, Zn content. In this article we have tried to compile information available on exploration of nutritional and processing quality related traits in Aegilops section and their utilization for wheat improvement by different approaches. [ABSTRACT FROM AUTHOR]

Published

2019

5. Anthocyanin bio-fortified colored wheat: Nutritional and functional characterization.

Author

Sharma, Saloni, Chunduri, Venkatesh, Kumar, Aman, Kumar, Rohit, Khare, Pragyanshu, Kondepudi, Kanthi Kiran, Bishnoi, Mahendra, and Garg, Monika

Subjects

*ANTHOCYANINS, *BIOFORTIFICATION, *WHEAT -- Nutrition, *BAKING industry, *PLANT breeders

Abstract

Colored wheat, rich in anthocyanins, has created interest among the breeders and baking industry. This study was aimed at understanding the nutritional and product making potential of our advanced, high yielding and regionally adapted colored wheat lines. Our results indicated that our advanced colored wheat lines exhibited higher anthocyanin content and antioxidant activity than donor wheat lines and it varied in the order of white

Published

2018

6. Rapid Development and Characterization of Chromosome Specific Translocation Line of Thinopyrum elongatum with Improved Dough Strength.

Author

Kumar, Aman, Garg, Monika, Kaur, Navneet, Chunduri, Venkatesh, Sharma, Saloni, Misser, Swati, Kumar, Ashish, Hisashi Tsujimoto, Quan-Wen Dou, and Gupta, Raj K.

Subjects

WHEAT, CHROMOSOMES

Abstract

The protein content and its type are principal factors affecting wheat (Triticum aestivum) end product quality. Among the wheat proteins, glutenin proteins, especially, high molecular weight glutenin subunits (HMW-GS) are major determinants of processing quality. Wheat and its primary gene pool have limited variation in terms of HMW-GS alleles. Wild relatives of wheat are an important source of genetic variation. For improvement of wheat processing quality its wild relative Thinopyrum elongatum with significant potential was utilized. An attempt was made to replace Th. elongatum chromosome long arm(1EL) carrying HMW-GS genes related to high dough strengthwith chromosome 1AL of wheat with least or negative effect on dough strength while retaining the chromosomes 1DL and 1BL with a positive effect on bread making quality. To create chromosome specific translocation line [1EL(1AS)], double monosomic of chromosomes 1E and 1A were created and further crossed with different cultivars and homoeologous pairing suppressor mutant line PhI. The primary selection was based upon glutenin and gliadin protein profiles, followed by sequential genomic in situ hybridization (GISH) and fluorescent in situ hybridization (FISH). These steps significantly reduced time, efforts, and economic cost in the generation of translocation line. In order to assess the effect of translocation on wheat quality, background recovery was carried out by backcrossing with recurrent parent for several generations and then selfing while selecting in each generation. Good recovery of parent background indicated the development of almost near isogenic line (NIL). Morphologically also translocation line was similar to recipient cultivar N61 that was further confirmed by seed storage protein profiles, RP-HPLC and scanning electron microscopy. The processing quality characteristics of translocation line (BC4F6) indicated significant improvement in the gluten performance index (GPI), dough mixing properties, dough strength, and extensibility. Our work aims to address the challenge of limited genetic diversity especially at chromosome 1A HMW-GS locus. We report successful development of chromosome 1A specific translocation line of Th. elongatum in wheat with improved dough strength. [ABSTRACT FROM AUTHOR]

Published

2017

7. Chromosome Specific Substitution Lines of Aegilops geniculata Alter Parameters of Bread Making Quality of Wheat.

Author

Garg, Monika, Tsujimoto, Hisashi, Gupta, Raj Kumar, Kumar, Aman, Kaur, Navneet, Kumar, Rohit, Chunduri, Venkatesh, Sharma, Nand Kishor, Chawla, Meenakshi, Sharma, Saloni, and Mundey, Jaspreet Kaur

Subjects

CHROMOSOMES, AEGILOPS, WHEAT quality, TRIPEPTIDES, MOLECULAR weights

Abstract

Wheat cultivars with wide introgression have strongly impacted global wheat production. Aegilops geniculata (MgUg) is an important wild relative with several useful traits that can be exploited for wheat improvement. Screening of Ae. geniculata addition lines indicated a negative effect of 1Ug and the positive effect of 1Mg chromosome on wheat dough strength. Negative effect of 1Ug is probably associated with variation in number and position of the tripeptide repeat motif in the high molecular weight glutenin (HMW-G) gene. To utilize the positive potential of 1Mg chromosome, three disomic substitution lines (DSLs) 1Mg(1A), 1Mg(1B) and 1Mg(1D) were created. These lines were characterized for morphological, cytogenetic properties and biochemical signatures using FISH, 1D-, 2D-PAGE and RP-HPLC. Contribution of wheat 1A, 1B and 1D chromosomes towards dough mixing and baking parameters, chapatti quality, Fe/Zn content and glume color were identified. Observed order of variation in the dough mixing and baking parameters {1Mg(1D) ≤wheat ≤1Mg(1B) ≤1Mg(1A)} indicated that chromosome specific introgression is desirable for best utilization of wild species’ potential. [ABSTRACT FROM AUTHOR]

Published

2016

8. Soft and Hard Textured Wheat Differ in Starch Properties as Indicated by Trimodal Distribution, Morphology, Thermal and Crystalline Properties.

Author

Kumar, Rohit, Kumar, Aman, Sharma, Nand Kishor, Kaur, Navneet, Chunduri, Venkatesh, Chawla, Meenakshi, Sharma, Saloni, Singh, Kashmir, and Garg, Monika

Subjects

THERMAL analysis, ENDOSPERM, PROTEIN expression, SUBSTITUTION reactions, CHEMICAL composition of plants

Abstract

Starch and proteins are major components in the wheat endosperm that affect its end product quality. Between the two textural classes of wheat i.e. hard and soft, starch granules are loosely bound with the lipids and proteins in soft wheat due to higher expression of interfering grain softness proteins. It might have impact on starch granules properties. In this work for the first time the physiochemical and structural properties of different sized starch granules (A-, B- and C-granules) were studied to understand the differences in starches with respect to soft and hard wheat. A-, B- and C-type granules were separated with >95% purity. Average number and proportion of A-, B-, and C-type granules was 18%, 56%, 26% and 76%, 19%, 5% respectively. All had symmetrical birefringence pattern with varied intensity. All displayed typical A-type crystallites. A-type granules also showed V-type crystallinity that is indicative of starch complexes with lipids and proteins. Granules differing in gelatinization temperature (ΔH) and transition temperature (ΔT), showed different enthalpy changes during heating. Substitution analysis indicated differences in relative substitution pattern of different starch granules. Birefringence, percentage crystallinity, transmittance, gelatinization enthalpy and substitution decreased in order of A>B>C being higher in hard wheat than soft wheat. Amylose content decreased in order of A>B>C being higher in soft wheat than hard wheat. Reconstitution experiment showed that starch properties could be manipulated by changing the composition of starch granules. Addition of A-granules to total starch significantly affected its thermal properties. Effect of A-granule addition was higher than B- and C-granules. Transmittance of the starch granules paste showed that starch granules of hard wheat formed clear paste. These results suggested that in addition to differences in protein concentration, hard and soft wheat lines have differences in starch composition also. [ABSTRACT FROM AUTHOR]

Published

2016

9. Transfer of Thinopyrum elongatum chromosome-specific 1EL.1AS translocation to hard wheat could not improve targeted bread-making quality - Failure and lessons learned.

Author

Kumar, Aman, Chunduri, Venkatesh, Sharma, Saloni, Kumar, Ashish, Kumari, Anita, Kapoor, Payal, Kaur, Satveer, and Garg, Monika

Subjects

*BREAD, *GLUTELINS, *FLOUR, *WHEAT, *BREAD quality, *GLIADINS, *INDIVIDUAL differences

Abstract

The end processing quality of bread wheat is affected by several parameters such as grain texture, grain protein content, and gluten protein composition. Gluten proteins (glutenins and gliadins) are associated with bread-making quality, and among gluten proteins, high molecular weight-glutenins (HMW-GS) are considered the major determinant of bread-making quality. Wild varieties of wheat serve as sources of the novel HMW-GS alleles that can be explored to improve wheat processing quality. HMW-GS specific to one such wild relative of wheat Thinopyrum elongatum has been reported to enhance the processing quality in the background of soft textured Japanese cultivar Norin61. In this study, we tried to transfer HMW-GS from Th. elongatum to hard textured, high yielding Indian cultivar PBW621. Two lines with different seed textures (Hard-TL and Soft-TL) were developed carrying 1EL.1AS translocation in PBW621 background. The effect of 1EL.1AS translocation on various quality parameters and bread-making quality was studied. Dough mixing properties, extensibility properties, and other quality parameters improved in hard and soft translocation lines. Comparing bread loaf volumes and bread quality scores suggested no significant differences in the improvement in individual quality parameters. [Display omitted] • M.A.S. based transfer of 1EL.1AS translocation to Indian cultivar PBW621. • Successful transfer of Th. elongatum specific HMW glutenins to wheat. • Development of two translocation lines with different grain textures. • SSR based background screening of two lines suggesting good background recovery. • Positive effect on individual quality parameters not reflected in terms of dough volume. [ABSTRACT FROM AUTHOR]

Published

2021

10. Evaluation of anthocyanin rich color wheat lines (black, blue, purple) for their cake making quality.

Author

Ali, Usman, Chaudhary, Era, Kaur, Satveer, Sharma, Anjali, Yadav, Mona, Kumari, Anita, Sheoran, Bhawna, Tiwari, Vandita, Sharma, Saloni, Tiwari, Apoorv, and Garg, Monika

Subjects

*CAKE, *FLOUR, *ANTHOCYANINS, *WHEAT, *GRAIN yields

Abstract

India mainly produces hard wheat suitable for good chapatti, and uses the same for cake making using additives. Recently, anthocyanin rich colored wheat (Black, Blue and Purple) has attracted attention. The study aimed to develop good cake making colored wheat line. A set of 37 colored wheat lines {9 white (W1-W9), 9 purple (P1-P9), 11 black (Bk1-Bk11), 8 blue (B1-B8)} were developed and screened for yield, grain, dough, flour, cake baking and sensory parameters. Two black wheat lines (Bk10 and Bk11) showed high yield and low grain hardness. The physicochemical characteristics of grain, flour, milling parameters and cake baking of Bk10 and BK11 {low protein 9.9% and 9.8% compared to control W9 (13.7%), high volume index 14 and 12.1 compared to control W9 (11.8), and low crumb hardness 1041.3 and 977.1g, compared to control W9 (1378.6 g)} confirmed suitability of these lines for cake making. These values were close to commercial premix (PM) control with added starch, emulsifiers and stabilizers that has low protein content (10.6%), high volume index 13.1 and low crumb hardness 806.1g. Despite baking, colored wheat cakes had 1.4 fold higher antioxidant activity than the control. Thus, Bk10 and BK11 have good commercial potential for exploitation and scale-up. [Display omitted] • Colored wheat lines were developed and evaluated for yield and cake quality. • Black wheat lines Bk10 and Bk11 showed good yield, cake quality, and sensory score. • This is the first report of anthocyanin-rich black wheat lines specific for cake. [ABSTRACT FROM AUTHOR]

Published

2023

11. Anthocyanin biofortified colored wheat modifies gut microbiota in mice.

Author

Kapoor, Payal, Kumari, Anita, Sheoran, Bhawna, Sharma, Saloni, Kaur, Simranjit, Bhunia, Rupam Kumar, Rajarammohan, Sivasubramanian, Bishnoi, Mahendra, Kondepudi, Kanthi Kiran, and Garg, Monika

Subjects

*GUT microbiome, *WHEAT, *MICE

Published

2022