The role of p-coumaric acid on physiological and biochemical response of chia seedling under salt stress

Nkomo, Mbukeni Andrew

January 2020

Philosophiae Doctor - PhD / The role of phenolic acids in mitigating salt stress tolerance have been well documented. However, there are contradicting reports on the effect of exogenously applied phenolic acids on the growth and development of various plants species. A general trend was observed where phenolic acids were shown to inhibit plant growth and development, with the exception of a few documented cases. One of these such cases is presented in this thesis. This study investigates the role of exogenously applied p-coumaric acid (p-CA) on physio-biochemical and molecular responses of chia seedlings under salt stress. This study is divided into three parts. Part one (Chapter 3) focuses on the impact of exogenous p-coumaric acid on the growth and development of chia seedlings. In this section, chia seedlings were supplemented with exogenous p-CA and the various biochemical and plant growth parameters were measured. The results showed that exogenous p-CA enhanced the growth of chia seedlings. An increase in chlorophyll, proline and superoxide oxide contents were also observed in the p-CA treatment relative to the control. We suggested that the increase in chia seedling growth could possibly be via the activation of reactive oxygen species-signalling pathway involving O2− under the control of proline accumulation (Chapter 3). Given the allopathy, nature of p-coumaric acid it is noteworthy that the response observed in this study may be species dependent, as contrasting responses have been reported in other plant species. Part two (Chapter 4) of this study investigates the influence of piperonylic acid (an inhibitor of endogenous p-coumaric acid) on the growth and development of chia seedlings. In trying to illustrate whether p-CA does play a regulatory role in enhancing pseudocereal plant growth, we treated chia seedlings with the irreversible inhibitor of C4H enzyme, to inhibit the biosynthesis of endogenous p-CA. In this section, chia seedlings were treated with piperonylic acid and changes in plant growth, ROS-induced oxidative damage, p-CA content and antioxidant capacity was monitored. Inhibition of endogenous p-CA restricted chia seedling growth by enhancing ROS-induced oxidative damage as seen for increased levels of superoxide, hydrogen peroxide and the extent of lipid peroxidation. Although an increase in antioxidant activity was observed in response to piperonylic acid, this increase was not sufficient to scavenge the ROS molecules to prevent oxidative damage and ultimate cellular death manifested as reduced plant growth. The results presented in this section support our hypothesis that p-CA play an important regulatory role in enhancing chia seedling growth and development as shown in Chapter 3. Part three (Chapter 5) seeks to identify and functionally characterise p-coumaric acid induced putative protein biomarkers under salt stress conditions in chia seedlings. Previous studies have shown that p-CA reversing the negative effect caused by NaCl-induced salt stress. While these studies were able to demonstrate the involvement of p-CA in promoting plant growth under salt stress conditions, they focussed primarily on the physiological aspect, which lacks in-depth biochemical and molecular analysis (ionomic and proteomic data) which could help in detecting the genes/proteins involved in salt stress tolerance mechanisms. A comparative ionomics and proteomic study was conducted, with the aim of elucidating the pivotal roles of essential macro elements and/or key protein markers involved in p-CA induced salt stress tolerance in chia seedlings. With the exception of Na, all the other macro elements were decreased in the salt treatment. Contrary to what was observed for the salt treatment most of the macro elements were increased in the p-CA treatment. However, the addition of exogenous p-CA to salt stressed seedlings showed an increase in essential macro elements such as Mg and Ca which have been shown to play a key role in plant growth and development. In the proteomic analysis we identified 907 proteins associated with shoots across all treatments. Interestingly, only eight proteins were conserved amongst all treatments. A total of 79 proteins were unique to the p-CA, 26 to the combination treatment (NaCl + p-CA) and only two proteins were unique to the salt stress treatment. The unique proteins identified in each of the treatments were functionally characterised to various subcellular compartments and biological processes. Most of the positively identified proteins were localised to the chloroplast and plays key roles in photosynthesis, transportation, stress responses and signal transduction pathways. Moreover, the protein biomarkers identified in this study (especially in the p-CA treatment) are putative candidates for genetic improvement of salt stress tolerance in plants.

Antioxidant enzymes

Ascorbate peroxidase

Chia

Chlorophyll

Glycine betaine

Lipid peroxidation

p-Coumaric acid

Peroxidase

Photosynthesis

Piperonylic acid

Plant proteomics

Proline

Pseudocereals

Reactive oxygen species

Salt stress

Superoxide radical

Superoxide dismutase

Osmoprotectant

Oxidative stress

Markers of Elevated Oxidative Stress in Oligodendrocytes Captured From the Brainstem and Occipital Cortex in Major Depressive Disorder and Suicide

Chandley, Michelle J., Szebeni, Attila, Szebeni, Katalin, Wang-Heaton, Hui, Garst, Jacob, Stockmeier, Craig A., Lewis, Nicole H., Ordway, Gregory A.

13 July 2022

Major depressive disorder (MDD) and suicide have been associated with elevated indices of oxidative damage in the brain, as well as white matter pathology including reduced myelination by oligodendrocytes. Oligodendrocytes highly populate white matter and are inherently susceptible to oxidative damage. Pathology of white matter oligodendrocytes has been reported to occur in brain regions that process behaviors that are disrupted in MDD and that may contribute to suicidal behavior. The present study was designed to determine whether oligodendrocyte pathology related to oxidative damage extends to brain areas outside of those that are traditionally considered to contribute to the psychopathology of MDD and suicide. Relative telomere lengths and the gene expression of five antioxidant-related genes, SOD1, SOD2, GPX1, CAT, and AGPS were measured in oligodendrocytes laser captured from two non-limbic brain areas: occipital cortical white matter and the brainstem locus coeruleus. Postmortem brain tissues were obtained from brain donors that died by suicide and had an active MDD at the time of death, and from psychiatrically normal control donors. Relative telomere lengths were significantly reduced in oligodendrocytes of both brain regions in MDD donors as compared to control donors. Three antioxidant-related genes (SOD1, SOD2, GPX1) were significantly reduced and one was significantly elevated (AGPS) in oligodendrocytes from both brain regions in MDD as compared to control donors. These findings suggest that oligodendrocyte pathology in MDD and suicide is widespread in the brain and not restricted to brain areas commonly associated with depression psychopathology.

depression

locus coeruleus

occipital cortex

oligodendrocytes

telomeres

antioxidants (metabolism)

depressive disorder

major (metabolism)

humans

locus coeruleus (metabolism)

occipital lobe

oligodendroglia (metabolism)

oxidative stress

suicide

superoxide dismutase-1 (metabolism)

Biomedical Sciences

Chemistry

Therapeutic suppression of mutant SOD1 by AAV9-mediated gene therapy approach in Amyotrophic Lateral Sclerosis

Likhite, Shibi B.

January 2014

No description available.

Biology

Biomedical Research

Immunology

Molecular Biology

Neurosciences

Neurobiology

Neurology

Virology

Amyotrophic Lateral Sclerosis, ALS

Superoxide Dismutase 1, SOD1

Adeno-associated vector 9, AAV9

short hairpin RNA, shRNA

Astrocytes

Neuroinflamation

Galectin 1, Gal1

Microglia

Optical Analysis of [Ca²⁺]i and Mitochondrial Signaling Pathways: Implications for the Selective Vulnerability of Motoneurons in Amyotrophic Lateral Sclerosis (ALS) / Optische Analysen von [Ca²⁺]i und mitochondrialen Signalwegen: Untersuchungen zur selektiven Verwundbarkeit von Motoneuronen in der amyotrophen Lateralsklerose (ALS)

Jaiswal, Manoj Kumar

23 January 2008

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Amyotrophe Lateralsklerose (ALS)

Superoxid-Dismutase 1 (SOD1)

Motoneuronerkrankungen

Kalzium-Puffer

Mitochondrien

Scheiben des Maushirnstamms

Ca²⁺ imaging

Multiphoton-Lasermikroskopie

Imaging of mitochondrien

Amyotrophic lateral sclerosis (ALS)

Superoxide dismutase 1 (SOD1)

Motoneuron Disease

Calcium buffers

Mitochondria

Brainstem slice

Ca²⁺ imaging

Multiphoton microscopy

Imaging of mitochondria

Biologie

Biology

Some aspects of molecular mechanisms of xenobiotics' hepatotoxicity and hepatoprotection : Modulatory roles of natural polyphenols

Lekic, Nataša

January 2013

Background & Aims: Oxidative stress and apoptosis are proposed mechanisms of cellular injury in studies of xenobiotic hepatotoxicity. The aim of this work is to find early signal markers of drug-induced injury of the liver by focusing on select antioxidant/oxidant and apoptotic genes. As well, to address the relationship between conventional liver dysfunction markers and the measured mRNA and protein expressions in the D-galactosamine/lipopolysaccharide and tert-butylhydroperoxide hepatotoxicity models. Furthermore, potential hepatoprotective capabilities of antioxidant polyphenols quercetin and curcumin were evaluated in relation to its modulation of the oxidative stress and apoptotic parameters in the given xenobiotic hepatotoxicity models. Methods: Biochemical markers testing the hepatic function included aminotransferases (ALT, AST) and bilirubin. Measurements of TBARS and conjugated dienes were used to assess lipoperoxidation. Plasma levels of catalase and reduced glutathione were used as indicators of the oxidative status of the cell. Real time PCR was used to analyse the mRNA expressions of the inducible nitric oxide synthase (NOS-2), heme oxygenase-1 (HO-1), superoxide dismutase (SOD-1), glutathione peroxidase (Gpx-1), caspase 3 (Casp3), BH3 interacting domain death agonist (Bid) and Bcl-2...

Optimizing CRISPR/Cas9 for Gene Silencing of SOD1 in Mouse Models of ALS

Kennedy, Zachary C.

09 August 2019

Mutations in the SOD1 gene are the best characterized genetic cause of amyotrophic lateral sclerosis (ALS) and account for ~20% of inherited cases and 1-3% of sporadic cases. The gene-editing tool Cas9 can silence mutant genes that cause disease, but effective delivery of CRISPR-Cas9 to the central nervous system (CNS) remains challenging. Here, I developed strategies using canonical Streptococcus pyogenes Cas9 to silence SOD1. In the first strategy, I demonstrate effectiveness of systemic delivery of guide RNA targeting SOD1 to the CNS in a transgenic mouse model expressing human mutant SOD1 and Cas9. Silencing was observed in both the brain and the spinal cord. In the second strategy, I demonstrate the effectiveness of delivering both guide RNA and Cas9 via two AAVs into the ventricles of the brain of SOD1G93A mice. Silencing was observed in the brain and in motor neurons within the spinal cord. For both strategies, treated mice had prolonged survival when compared to controls. Treated mice also had improvements in grip strength and rotarod function. For ICV treated mice, we detected a benefit of SOD1 silencing using net axonal transport assays, a novel method to detect motor neuron function in mice before onset of motor symptoms. These studies demonstrate that Cas9-mediated genome editing can mediate disease gene silencing in motor neurons and warrants further development for use as a therapeutic intervention for SOD1-linked ALS patients.

CRISPR/Cas9

Cas9

Amyotrophic lateral sclerosis

ALS

Motor Neuron Disease

SOD1

superoxide dismutase

gene therapy

gene editing

AAV

adeno associated vector

adeno-associated vector

AAV9

Biology

Biotechnology

Molecular and Cellular Neuroscience

Musculoskeletal Diseases

Nervous System Diseases

Other Neuroscience and Neurobiology

Therapeutics