Your search keyword '"Sindho Wagan"' showing total 5 results

1. Deciphering the role of WRKY transcription factors in plant resilience to alkaline salt stress

Author

Sindho Wagan, Maqsood Ali, Muneer Ahmed Khoso, Intikhab Alam, Khuzin Dinislam, Amjad Hussain, Nazir Ahmed Brohi, Hakim Manghwar, and Fen Liu

Subjects

WRKY transcription factors, Salt stress, Saline-alkali stress, Regulatory process, Hormonal signaling, Plant ecology, QK900-989

Abstract

The WRKY gene family consists of unique transcription factors (TFs) found exclusively in plants. These TFs play a crucial role in regulating how plants respond to various abiotic stresses, such as saline-alkaline conditions, temperature fluctuations, drought, UV radiation and others. Scientists have been progressively studying the roles and mechanisms of WRKY in several plant species, including both model plants and essential agricultural crops. This study focus has emerged due to the understanding that alkaline and saline soil stressors considerably impede global agricultural productivity. Multiple research efforts have underscored the significant biological functions of WRKY TFs in assisting plants in coping with various abiotic challenges, particularly in enhancing their ability to withstand alkaline-salt stress. This review aims to investigate the structural capabilities of WRKY TFs and their impact on plant responses to alkaline and salt stresses. Additionally, it seeks to elucidate the role of these TFs in alleviating diverse abiotic and biotic stressors. The objective of this review study is to provide comprehensive insights into the current state of the field and the importance of WRKY TFs in regulating plant responses to salt and alkaline stress.

Published

2024

2. Exploring the mechanisms of WRKY transcription factors and regulated pathways in response to abiotic stress

Author

Shenglin Li, Muneer Ahmed Khoso, Jiabo Wu, Baogang Yu, Sindho Wagan, and Lijie Liu

Subjects

WRKY TFs, Molecular mechanism, Signaling pathways, Abiotic stress, Plant growth and development, Plant ecology, QK900-989

Abstract

The environmental conditions encompassing plants exert a significant impact on their appropriate growth and development. It is of utmost importance to investigate the mechanisms and signaling cascades underlying the tolerance of plants to abiotic stress in order to enhance the quality of crops. Plant growth and development processes are significantly impacted by abiotic stresses, which are intricately linked to their surroundings. Plants exhibit prompt genetic and metabolic network responses, mostly through signaling networks involving transcription factors that respond to stress, including WRKY, MYB, bZIP, AP2/EREBP, and NAC. Among these WRKY TFs transcription factors, fulfill a pivotal function in a diverse range of stress responses and developmental mechanisms. WRKY TFs greatly assist plants in coping with abiotic stress. These transcription factors oversee the control of several target gene categories and active involvement in numerous signaling cascades in plants through their interaction with the W-box cis-acting elements located in the promoters of these target genes.This research provides a comprehensive analysis of the signaling networks linked to WRKY TFs and their response mechanism to abiotic stress. In addition, we have explored the state of knowledge on WRKY TFs' effects on plants' response to a range of abiotic stresses, such as drought, salt, high temperatures, and cold. It elucidates the intricate molecular mechanisms by which WRKY TFs govern signaling pathways and modulate gene expression, thereby conferring stress tolerance upon plants. Moreover, we have summarized the molecular function of WRKY TFs that are involved in tolerance to biotic stress. WRKY TFs, involved in signaling networks and hormonal routes like SA and JA, aid plants in inducing resistance mechanisms and coordinating defense responses against pathogens and environmental challenges. In order to enhance agricultural sustainability and augment crop resilience towards stress, strategies to manipulate the intricate regulatory networks involving WRKY TFs need to be established.

Published

2024

3. WRKY Transcription Factors (TFs) as Key Regulators of Plant Resilience to Environmental Stresses: Current Perspective

Author

Shenglin Li, Muneer Ahmed Khoso, He Xu, Chao Zhang, Ziyang Liu, Sindho Wagan, Khuzin Dinislam, and Lijie Liu

Subjects

WRKY TFs, growth and development in plants, regulatory mechanism, signaling pathways, biotic and abiotic stresses, Agriculture

Abstract

Plants encounter various stresses in their natural environments and can effectively respond to only one stress at a time. Through a complex gene network, transcription factors (TFs) such as WRKY TFs regulate a diverse array of stress responses. The clarification of the structural characteristics of WRKY proteins, along with recent advancements in molecular dynamics simulations, has shed light on the formation, stability, and interactions of DNA–protein complexes. This has provided a novel viewpoint regarding the control of WRKY TFs. The investigation of superfamilies, encompassing their historical development, diversity, and evolutionary patterns, has become feasible due to the transcriptome approach’s capacity to provide extensive and comprehensive transcripts. The significance of WRKY TFs lies in their pivotal role within several signaling cascades and regulatory networks that influence plant defense responses. The present review summarizes the functional aspects of the high-volume sequence data of WRKY TFs from different species studied to date. Moreover, a comparative analysis approach was utilized to determine the functions of the identified WRKY TFs in response to both abiotic and biotic stresses, as revealed through numerous studies on different plant species. The results of this review will be pivotal in understanding evolutionary events and the significance of WRKY TFs in the context of climate change, incorporating new scientific evidence to propose an innovative viewpoint.

Published

2024

4. Impact of plant growth-promoting rhizobacteria (PGPR) on plant nutrition and root characteristics: Current perspective

Author

Muneer Ahmed Khoso, Sindho Wagan, Intikhab Alam, Amjad Hussain, Qurban Ali, Sudipta Saha, Tika Ram Poudel, Hakim Manghwar, and Fen Liu

Subjects

PGPR, Rhizosphere, Root trait, Phytohormones, Plant nutrition, Plant ecology, QK900-989

Abstract

Through a variety of mechanisms, including increasing the amount of readily available mineral nutrients, regulating phytohormone levels, and biocontrol of phytopathogens, plant growth-promoting rhizobacteria (PGPR) associated with the plant rhizosphere either directly or indirectly stimulates plant growth and development. The establishment, survival, and persistence of PGPR inoculants are widely acknowledged to be contingent upon these two parameters, in addition to the intricate network of interactions within the rhizosphere. In general, the soil is a moist environment with significant amounts of carbon that have been degraded and harbors a large population of soil microbes. The rhizo-microbiome is crucial to agriculture because a wide variety of root exudates and plant cell debris attract unique and distinct patterns of microbial colonization. The rhizo-microbiome plays a crucial role in the manufacture and regulation of extracellular molecules, including hormones, secondary metabolites, antibiotics, and various signaling chemicals. Additionally, the microbial composition within the rhizo-microbiome influences soil texture enhancement. Research has shown that PGPR can be used to treat plants or inoculate plants to promote plant development. PGPR alters the physiology of the entire plant, which enhances nutrient uptake and affects the effectiveness of root activity. The specific biochemical processes of plants involved in this phenomenon are often not well understood. Nevertheless, new studies have shed light on the mechanisms via which signaling by PGPR can induce various plant responses, both at the local and systemic levels. Insufficient information is available regarding the impact of the PGPR mechanism and molecules on metabolic pathways in root characteristics. Consequently, this review will concentrate on elucidating the PGPR mechanism and identifying the essential molecules that exert influence on root-microbe interactions.

Published

2024

5. Synergism of vesicle trafficking and cytoskeleton during regulation of plant growth and development: A mechanistic outlook

Author

Muneer Ahmed Khoso, Hailong Zhang, Mir Hassan Khoso, Tika Ram Poudel, Sindho Wagan, Tamar Papiashvili, Sudipta Saha, Abid Ali, Ghulam Murtaza, Hakim Manghwar, and Fen Liu

Subjects

Vesicular trafficking, Tethering, Cytoskeleton, Coat protein complexes, SNAREs, PIN, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

The cytoskeleton is a fundamental component found in all eukaryotic organisms, serving as a critical factor in various essential cyto-biological mechanisms, particularly in the locomotion and morphological transformations of plant cells. The cytoskeleton is comprised of three main components: microtubules (MT), microfilaments (MF), and intermediate filaments (IF). The cytoskeleton plays a crucial role in the process of cell wall formation and remodeling throughout the growth and development of cells. It is a highly organized and regulated network composed of filamentous components. In the basic processes of intracellular transport, such as mitosis, cytokinesis, and cell polarity, the plant cytoskeleton plays a crucial role according to recent studies. The major flaws in the organization of the cytoskeletal framework are at the root of the aberrant organogenesis currently observed in plant mutants. The regulation of protein compartmentalization and abundance within cells is predominantly governed by the process of vesicle/membrane transport, which plays a crucial role in several signaling cascades.The regulation of membrane transport in eukaryotic cells is governed by a diverse array of proteins. Recent developments in genomics have provided new tools to study the evolutionary relationships between membrane proteins in different plant species. It is known that members of the GTPases, COP, SNAREs, Rabs, tethering factors, and PIN families play essential roles in vesicle transport between plant, animal, and microbial species. This Review presents the latest research on the plant cytoskeleton, focusing on recent developments related to the cytoskeleton and summarizing the role of various proteins in vesicle transport. In addition, the report predicts future research direction of plant cytoskeleton and vesicle trafficking, potential research priorities, and provides researchers with specific pointers to further investigate the significant link between cytoskeleton and vesicle trafficking.

Published

2023