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Muhammad Waqas,Muhammad Tehseen Azhar,Iqrar Ahmad Rana,Farrukh Azeem,Muhammad Amjad Ali,Muhammad Amjad Nawaz,정규화,Rana Muhammad Atif 한국유전학회 2019 Genes & Genomics Vol.41 No.4
Background WRKY proteins play a vital role in the regulation of several imperative plant metabolic processes and pathways, especially under biotic and abiotic stresses. Although WRKY genes have been characterized in various major crop plants, their identification and characterization in pulse legumes is still in its infancy. Chickpea (Cicer arietinum L.) is the most important pulse legume grown in arid and semi-arid tropics. Objective In silico identification and characterization of WRKY transcription factor-encoding genes in chickpea genome. Methods For this purpose, a systematic genome-wide analysis was carried out to identify the non-redundant WRKY transcription factors in the chickpea genome. Results We have computationally identified 70 WRKY-encoding non-redundant genes which were randomly distributed on all the chickpea chromosomes except chromosome 8. The evolutionary phylogenetic analysis classified the WRKY proteins into three major groups (I, II and III) and seven sub-groups (IN, IC, IIa, IIb, IIc, IId and IIe). The gene structure analysis revealed the presence of 2–7 introns among the family members. Along with the presence of absolutely conserved signatory WRKY domain, 19 different domains were also found to be conserved in a group-specific manner. Insights of gene duplication analysis revealed the predominant role of segmental duplications for the expansion of WRKY genes in chickpea. Purifying selection seems to be operated during the evolution and expansion of paralogous WRKY genes. The transcriptome data-based in silico expression analysis revealed the differential expression of CarWRKY genes in root and shoot tissues under salt, drought, and cold stress conditions. Moreover, some of these genes showed identical expression pattern under these stresses, revealing the possibility of involvement of these genes in conserved abiotic stress–response pathways. Conclusion This genome-wide computational analysis will serve as a base to accelerate the functional characterization of WRKY TFs especially under biotic and abiotic stresses.
TinyOS-New Trends, Comparative Views, and Supported Sensing Applications: A Review
Amjad, Muhammad,Sharif, Muhammad,Afzal, Muhammad Khalil,Sung Won Kim IEEE 2016 IEEE SENSORS JOURNAL Vol.16 No.9
<P>The wireless sensor network (WSN) is an interesting area for modern day research groups. Tiny sensor nodes are deployed in a diversity of environments but with limited resources. Scarce resources compel researchers to employ an operating system that requires limited memory and minimum power. Tiny operating system (TinyOS) is a widely used operating system for sensor nodes, which provides concurrency and flexibility while adhering to the constraints of scarce resources. Comparatively, TinyOS is considered to be the most robust, innovative, energy-efficient, and widely used operating system in sensor networks. This paper looks at the state-of-the-art TinyOS and the different dimensions of its design paradigm, programming model, execution model, scheduling algorithms, concurrency, memory management, hardware support platforms, and other features. The addition of different features in TinyOS makes it the operating system of choice for WSNs. Sensing nodes with TinyOS seem to show more flexibility in supporting diverse types of sensing applications.</P>
Genome and transcriptome-wide analyses of cellulose synthase gene superfamily in soybean
Nawaz, Muhammad Amjad,Rehman, Hafiz Mamoon,Baloch, Faheem Shehzad,Ijaz, Babar,Ali, Muhammad Amjad,Khan, Iqrar Ahmad,Lee, Jeong Dong,Chung, Gyuhwa,Yang, Seung Hwan G. Fischer 2017 Journal of plant physiology Vol. No.
<P><B>Abstract</B></P> <P>The plant cellulose synthase gene superfamily belongs to the category of type-2 glycosyltransferases, and is involved in cellulose and hemicellulose biosynthesis. These enzymes are vital for maintaining cell-wall structural integrity throughout plant life. Here, we identified 78 putative cellulose synthases (CS) in the soybean genome. Phylogenetic analysis against 40 reference <I>Arabidopsis</I> CS genes clustered soybean CSs into seven major groups (CESA, CSL A, B, C, D, E and G), located on 19 chromosomes (except chromosome 18). Soybean CS expansion occurred in 66 duplication events. Additionally, we identified 95 simple sequence repeat makers related to 44 CSs. We next performed digital expression analysis using publically available datasets to understand potential CS functions in soybean. We found that CSs were highly expressed during soybean seed development, a pattern confirmed with an Affymatrix soybean IVT array and validated with RNA-seq profiles. Within CS groups, CESAs had higher relative expression than CSLs. Soybean CS models were designed based on maximum average RPKM values. Gene co-expression networks were developed to explore which CSs could work together in soybean. Finally, RT-PCR analysis confirmed the expression of 15 selected CSs during all four seed developmental stages.</P>
Muhammad Amjad,Javaid Akhtar,Behzad Murtaza,Ghulam Abbas,Husnain Jawad 한국원예학회 2016 Horticulture, Environment, and Biotechnology Vol.57 No.3
To quantify the effect of two potassium levels (4.5 and 9.0 mM) on salt tolerance, we conducted a solution culture experiment using salt-tolerant (Nagina) and salt-sensitive (Peto-86) Solanum lycopersicum (tomato) cultivars grown under NaCl stress (0, 75, and 150 mM). Potassium is known to minimize oxidative stress and enhance photosynthesis in salt-stressed plants. A 30-day treatment with potassium, differentially increased stomatal conductance and transpiration, decreased oxidative stress, lowered the activities of antioxidant enzymes (i.e., superoxide dismutase, catalase, and glutathione reductase), increased leaf K+ levels and the K+/Na+ ratio, and improved the membrane stability index in the salt-tolerant and salt-sensitive tomato cultivars exposed to salt stress. The salt-sensitive cultivar had significantly higher malondialdehyde (MDA) concentrations and lower antioxidant enzyme activity than the salt-tolerant cultivar. These results indicate that potassium can be used to alleviate salt-induced oxidative stress and photosynthetic limitations in tomato plants and ultimately improve survival under salt stress.
Muhammad Ahmed Farooqui,Muhammad Umar,Muhammad Amjad Sabir,Rashid Pervez,Tarib Jalees 한국지질과학협의회 2019 Geosciences Journal Vol.23 No.2
Detailed geochemical analyses of clastic fraction of the oldest exposed Salt Range Formation in the famous salt producing region (Salt and Trans-Indus Ranges) Pakistan was carried out in order to understand provenance, paleoclimate, depositional and tectonic settings. Sandstone and shale samples of Salt Range Formation were analysed for major, trace and rare earth elements and various geochemical models and ratios were used to interpret. Geochemical analyses of both sandstone and shale fraction mostly display similar results and interpretations. The samples are classified as arkose, subarkose, litharenites and were sourced from felsic and/or intermediate igneous rocks. The sedimentation of the detritus was occurred in fluvial to restricted shelf conditions under arid to semi-arid and oxygenated climate conditions. The tectonic settings of the sediments were mainly Oceanic and Continental Island arcs as well as Active Continental margin.
Muhammad Amjad,Zainal Salam,Mochammad Facta,Kashif Ishaque 전력전자학회 2012 JOURNAL OF POWER ELECTRONICS Vol.12 No.3
It is known that transformer based power supplies for ozone generators have low efficiency, high cost and exhibits a limited frequency range of operation. To overcome these disadvantages, this paper proposes a high frequency ozone generator with the absence of a transformer. The voltage step-up is achieved only by utilizing the resonant tank. This is made possible by a novel combination of ozone chamber materials that allow ozone to be generated at only 1.5 ? 3.5 ㎸p-p. The input to the resonant tank is driven by a PWM full bridge resonant inverter. Furthermore, zero-current zero-voltage switching (ZCZVS) operation is achieved by employing a duty factor of 25% between the switches of the full bridge. The advantages of the proposed system include high efficiency, low cost and the ability to control ozone production by varying the input voltage to the inverter. The prototype is verified by both simulation and experimental results.
Amjad, Muhammad,Salam, Zainal,Facta, Mochammad,Ishaque, Kashif The Korean Institute of Power Electronics 2012 JOURNAL OF POWER ELECTRONICS Vol.12 No.3
It is known that transformer based power supplies for ozone generators have low efficiency, high cost and exhibits a limited frequency range of operation. To overcome these disadvantages, this paper proposes a high frequency ozone generator with the absence of a transformer. The voltage step-up is achieved only by utilizing the resonant tank. This is made possible by a novel combination of ozone chamber materials that allow ozone to be generated at only 1.5 - 3.5 $kV_{p-p}$. The input to the resonant tank is driven by a PWM full bridge resonant inverter. Furthermore, zero-current zero-voltage switching (ZCZVS) operation is achieved by employing a duty factor of 25% between the switches of the full bridge. The advantages of the proposed system include high efficiency, low cost and the ability to control ozone production by varying the input voltage to the inverter. The prototype is verified by both simulation and experimental results.