Your search keyword '"Karunakaran, Chithra"' showing total 4 results

1. Synchrotron-based spectroscopy and imaging reveal changes in the cell-wall composition of barley leaves in defence responses to Blumeria graminis f. sp. tritici.

Author

Lahlali, Rachid, Song, Tao, Chu, Mingguang, Karunakaran, Chithra, Yu, Fengqun, Wei, Yangdou, and Peng, Gary

Subjects

COMPOSITION of leaves, SPECTRAL imaging, ERYSIPHE graminis, BETA-glucans, POWDERY mildew diseases, PECTINS, FOCAL plane arrays sensors, PLANT cell walls

Abstract

Copyright of Canadian Journal of Plant Pathology is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

2. Cell Wall Biomolecular Composition Plays a Potential Role in the Host Type II Resistance to Fusarium Head Blight in Wheat.

Author

Lahlali, Rachid, Kumar, Saroj, Lipu Wang, Forseille, Li, Sylvain, Nicole, Korbas, Malgorzata, Muir, David, Swerhone, George, Lawrence, John R., Fobert, Pierre R., Peng, Gary, Karunakaran, Chithra, Cordero, Radames J. B., and Bellincampi, Daniela

Subjects

FUSARIUM diseases of plants, GRAIN disease & pest resistance, PLANT cell walls

Abstract

Fusarium head blight (FHB) is a serious disease of wheat worldwide. Cultivar resistance to FHB depends on biochemical factors that confine the pathogen spread in spikes. Breeding for cultivar resistance is considered the most practical way to manage this disease. In this study, different spectroscopy and microscopy techniques were applied to discriminate resistance in wheat genotypes against FHB. Synchrotron-based spectroscopy and imaging techniques, including focal plane array infrared and X-ray fluorescence (XRF) spectroscopy were used to understand changes in biochemical and nutrients in rachis following FHB infection. Sumai3 and Muchmore were used to represent resistant and susceptible cultivars to FHB, respectively, in this study. The histological comparison of rachis showed substantial differences in the cell wall thickness between the cultivars after infection. Synchrotron-based infrared imaging emphasized substantial difference in biochemical composition of rachis samples between the two cultivars prior to visible symptoms; in the resistant Sumai3, infrared bands representing lignin and hemicellulose were stronger and more persistent compared to the susceptible cultivar. These bands may be the candidates of biochemical markers for FHB resistance. Focal plane array infrared imaging (FPA) spectra from the rachis epidermis and vascular bundles revealed a new band (1710 cm-1) related to the oxidative stress on the susceptible cultivar only. XRF spectroscopy data revealed differences in nutrients composition between cultivars, and between controls and inoculated samples, with substantial increases observed for Ca, K, Mn, Fe, Zn, and Si in the resistant cultivar. These nutrients are related to cell wall stability, metabolic process, and plant defense mechanisms such as lignification pathway and callose deposition. The combination of cell wall composition and lignification plays a role in the mechanism of type II host resistance to FHB. Biochemical profiling using the synchrotron-based spectroscopy holds potential for screening wheat genotypes for FHB resistance. [ABSTRACT FROM AUTHOR]

Published

2016

3. Infrared spectroscopy combined with imaging: A new developing analytical tool in health and plant science.

Author

Kumar, Saroj, Lahlali, Rachid, Liu, Xia, and Karunakaran, Chithra

Subjects

CARBOHYDRATES, FOURIER transform infrared spectroscopy, PLANT cell walls, EFFECT of environment on plants, BOTANICAL research

Abstract

Modern infrared (IR) spectroscopy and imaging has a wide range of applications in health and plant sciences. Initially, it was extensively used for the study of proteins, nucleotides, lipids and carbohydrates. With time, its use has extended to disease assessment to discriminate healthy and diseased samples on the basis of chemical changes. The application of an advanced focal plane array detector, which is able to scan a large area of samples in a short time, helps in investigating specific changes that could be correlated with different environmental stresses. An IR microscope connected with a synchrotron light source further enhances the lateral spatial resolution at diffraction limit because of the compact beam size. For example, synchrotron-based IR spectroscopy imaging in combination with multivariate statistical analysis has been proven to be a powerful non-destructive analytical tool to probe changes in plant cell wall composition/structure in response to biological processes and environmental stresses. New development of nano-Fourier transform infrared spectroscopy (FTIR) combined with scattering type scanning near-field optical microscopy breaks the diffraction limitation, which opens the new area of applications. This review focuses on a new area of diagnostic research as well as development of IR spectroscopy and imaging for biological specimens including compositional changes in plant cell wall. [ABSTRACT FROM PUBLISHER]

Published

2016

4. Direct and up-close views of plant cell walls show a leading role for lignin-modifying enzymes on ensuing xylanases.

Author

Jeremic, Dragica, Goacher, Robyn E., Ruoyu Yan, Karunakaran, Chithra, and Master, Emma R.

Subjects

PLANT enzyme analysis, CARBON content of plant biomass, LIGNOCELLULOSE biodegradation, PLANT cell walls, LIGNINS, XYLANASES, PLANT fibers, SCANNING transmission electron microscopy

Abstract

Background: A key barrier that limits the full potential of biological processes to create new, sustainable materials and fuels from plant fibre is limited enzyme accessibility to polysaccharides and lignin that characterize lignocellulose networks. Moreover, the heterogeneity of lignocellulosic substrates means that different enzyme combinations might be required for efficient transformation of different plant resources. Analytical techniques with high chemical sensitivity and spatial resolution that permit direct characterization of solid samples could help overcome these challenges by allowing direct visualization of enzyme action within plant fibre, thereby identify barriers to enzyme action. Results: In the current study, the high spatial resolution (about 30 nm) of scanning transmission X-ray microscopy (STXM), and the detection sensitivity (ppm) of time-of-flight secondary ion mass spectrometry (ToF-SIMS), were harnessed for the first time to investigate the progression of laccase, cellulase and xylanase activities through wood samples, and to evaluate complementary action between lignin-modifying and polysaccharide-degrading enzymes. In particular, complementary insights from the STXM and ToF-SIMS analyses revealed the key role of laccase in promoting xylanase activity throughout and between plant cell walls. Conclusions: The spatial resolution of STXM clearly revealed time-dependent progression and spatial distribution of laccase and xylanase activities, whereas ToF-SIMS analyses confirmed that laccase promoted protein penetration into fibre samples, leading to an overall increase in polysaccharide degradation. Spectromicroscopic visualizations of plant cell wall chemistry allowed simultaneous tracking of changes to lignin and polysaccharide contents, which provides new possibilities for investigating the complementary roles of lignin-modifying and carbohydrate-active enzymes. [ABSTRACT FROM AUTHOR]

Published

2014