Metal-protein interactome in plant mitochondria

Tan, Yew-Foon

January 2009

[Truncated abstract] Transition metals in the plant mitochondrion have dual roles in regulating the function of the organelle. While metals participate in mitochondrial respiratory metabolism as ligands in bioenergetic, detoxifying, and various other metabolic enzymes, a breakdown in metal homeostasis during oxidative stress can perpetuate the cycling of ROS by redox active metal ions. Large-scale studies into the duplicitous roles of metal ions in biological systems has been lacking and in this thesis, a combination of metallomics, database annotations, membrane proteomics, metal-protein interactomics, structural biology, functional assays and mass spectrometry were all used to gain a clearer insight into the involvement of metal ions in affecting plant mitochondrial function. The Arabidopsis mitochondrion was shown to contain the transition metals cobalt, copper, iron, manganese, molybdenum, and zinc. Interestingly, the redox active copper and iron represented 75% of the mitochondrial metallome and these metal species were revealed to be highly labile during oxidative stress suggesting a possible contribution of metal-catalysed oxidation (MCO) in the damage of biological macromolecules. Bioinformatic analysis of metalloproteins predicted and experimentally determined to be mitochondrially localised revealed that metal ion transporters are poorly characterised. An in-depth proteomic analysis of the membrane proteome was conducted on mitochondria isolated from unstressed and stressed cell cultures resulted in the identification of stress-responsive as well as potential metal ion transporters. Also, many of the annotated metalloproteins predicted to be mitochondrial lack experimental evidence for subcellular localisation. ... However, based on evidence in the literature, it was hypothesised that metal-interacting sites may be the targets for MCO due to their affinity for metal ions. Attempts were made to identify the site specificity of MCO on mitochondrial proteins but no carbonyl sites could be found owing to technical problems associated with non-specific binding of proteins to the enrichment resin and low abundance of the labelled protein carbonyls. The use of the model protein BSA showed that protein oxidation occurs in clusters and the use of model peptides demonstrated that the ability of amino acid residues to complex metal ions is important in dictating susceptibility to MCO. Further experimental verification for the site specificity of MCO is required to determine the consequences of MCO on mitochondrial protein function. Overall, this thesis provided a large-scale analysis of the contributions of metal ions to mitochondrial respiratory metabolism with an emphasis on metal ion induced toxicity. Using multi-facetted approaches, an insight into the dynamic nature of mitochondrial metal homeostasis, stress responsive transporters, the interactions of metal ions with mitochondrial proteins and the possible mechanism in which proteins are specifically oxidised by MCO has been uncovered paving the way for future focused studies characterising the consequences of oxidative stress on specific proteins and their function.

Plant mitochondria

Metalloproteins

Oxidative stress

Mitochondria

Proteomics

Metal

Oxidative stress

Proteomic biomarker discovery for preeclampsia

Atkinson, Kelly Rene LeFevre

January 2008

Preeclampsia is a serious multisystem complication of late pregnancy with adverse effects for mothers and babies. Currently this disorder is diagnosed from clinical observations occurring late in the disease process. Unknown factors in the maternal circulation, possibly released by the preeclamptic placenta, have been linked to the pathophysiological changes characteristic of the disorder. The research in this thesis used proteomic techniques to identify putative preeclampsia biomarkers from two sources: secreted from a placental cell line undergoing differentiation, and directly sampled from the serum and plasma of women with late-onset preeclampsia. The first part of this research examined the secreted proteome of a placental choriocarcinoma cell line (BeWo) undergoing forskolin-mediated differentiation. Development of serum-free culture techniques enabled analysis of these secreted proteins by two-dimensional gel electrophoresis (2DE). Statistical testing revealed the significant involvement of seven spots during this differentiation model, with VE-cadherin and matrix metalloproteinase 2 among the proteins identified. In the second part of this research, maternal serum and plasma proteins were compared from women with preeclampsia and healthy pregnant women. Serum samples were analyzed using 2DE, and plasma was subjected to difference gel electrophoresis (DIGE). Bioinformatic analysis of both datasets identified multiple spot clusters able to classify samples according to disease state. Five of these serum proteins were differentially regulated in preeclampsia, including two isoforms of apolipoprotein E whose isoform-specific expression was confirmed using western blots. Analysis of plasma from preeclamptic women identified six proteins, again including apolipoprotein E. Proteins from both studies are linked to preeclampsia pathophysiology through lipid transport, complement, and retinol transport systems. The culture methods and secreted proteomic techniques developed in this work have uncovered proteins in a placental cell line and maternal serum and plasma that are associated with preeclampsia. These methods can be extended to any system where secreted proteins are of interest. The differentially regulated proteins found in this study provide an important first step towards developing effective biomarkers for diagnosing and/or predicting preeclampsia.

proteomics

pregnancy

A quantitative proteomics investigation of cold adaptation in the marine bacterium, Sphinopyxis alaskensis

Ting, Lily Li Jing, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2010

The marine bacterium Sphingopyxis alaskensis was isolated as one of the most numerically abundant bacteria from cold (4–10??C) nutrient depleted waters in the North Pacific Ocean. The objective of this study was to examine cold adaptation of S. alaskensis by using proteomics to examine changes in global protein levels caused by growth at low (10??C) and high (30??C) temperatures. Stable isotope labelling-based quantitative proteomics was used, and a rigorous post-experimental data processing workflow adapted from microarray-based methods was developed. The approach included metabolic labelling with 14N/15N and normalisation and statistical testing of quantitative proteomics data. Approximately 400,000 tandem mass spectra were generated resulting in the confident identification of 2,135 proteins (66% genome coverage) and the quantitation of 1,172 proteins (37% genome coverage). Normalisation approaches were evaluated using cultures grown at 30??C and labelled with 14N and 15N. For 10??C vs. 30??C experiments, protein quantities were normalised within each experiment using a multivariate lowess approach. Statistical significance was assessed by combining data from all experiments and applying a moderated t-test using the empirical Bayes method with the limma package in R. Proteins were ranked after calculating the B-statistic and the Storey-Tibshirani false discovery rate. 217 proteins (6% genome coverage) were determined to have significant quantitative differences. In achieving these outcomes a range of factors that impact on quantitative proteomics data quality were broadly assessed, resulting in the development of a robust approach that is generally applicable to quantitative proteomics of biological system. The significantly differentially abundant proteins from the proteomics data provided insight into molecular mechanisms of cold adaptation in S. alaskensis. Important aspects of cold adaptation included cell membrane restructuring, exopolysaccharide biosynthesis, lipid degradation, carbohydrate and amino acid metabolism, and increased capacity of transcriptional and translational processes. A number of cold adaptive responses in S. alaskensis were novel, including a specific cold-active protein folding pathway, a possible thermally-controlled stringent response, and biosynthesis of intracellular polyhydroxyalkanoate reserve material. The overall study provided important new insight into the evolution of growth strategies necessary for the effective competition of S. alaskensis in cold, oligotrophic environments.

Cold adaptation

Quantitative proteomics

Extremophiles

Mass spectrometry

Marine bacteria

A quantitative proteomics investigation of cold adaptation in the marine bacterium, Sphinopyxis alaskensis

Ting, Lily Li Jing, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2010

The marine bacterium Sphingopyxis alaskensis was isolated as one of the most numerically abundant bacteria from cold (4–10??C) nutrient depleted waters in the North Pacific Ocean. The objective of this study was to examine cold adaptation of S. alaskensis by using proteomics to examine changes in global protein levels caused by growth at low (10??C) and high (30??C) temperatures. Stable isotope labelling-based quantitative proteomics was used, and a rigorous post-experimental data processing workflow adapted from microarray-based methods was developed. The approach included metabolic labelling with 14N/15N and normalisation and statistical testing of quantitative proteomics data. Approximately 400,000 tandem mass spectra were generated resulting in the confident identification of 2,135 proteins (66% genome coverage) and the quantitation of 1,172 proteins (37% genome coverage). Normalisation approaches were evaluated using cultures grown at 30??C and labelled with 14N and 15N. For 10??C vs. 30??C experiments, protein quantities were normalised within each experiment using a multivariate lowess approach. Statistical significance was assessed by combining data from all experiments and applying a moderated t-test using the empirical Bayes method with the limma package in R. Proteins were ranked after calculating the B-statistic and the Storey-Tibshirani false discovery rate. 217 proteins (6% genome coverage) were determined to have significant quantitative differences. In achieving these outcomes a range of factors that impact on quantitative proteomics data quality were broadly assessed, resulting in the development of a robust approach that is generally applicable to quantitative proteomics of biological system. The significantly differentially abundant proteins from the proteomics data provided insight into molecular mechanisms of cold adaptation in S. alaskensis. Important aspects of cold adaptation included cell membrane restructuring, exopolysaccharide biosynthesis, lipid degradation, carbohydrate and amino acid metabolism, and increased capacity of transcriptional and translational processes. A number of cold adaptive responses in S. alaskensis were novel, including a specific cold-active protein folding pathway, a possible thermally-controlled stringent response, and biosynthesis of intracellular polyhydroxyalkanoate reserve material. The overall study provided important new insight into the evolution of growth strategies necessary for the effective competition of S. alaskensis in cold, oligotrophic environments.

Cold adaptation

Quantitative proteomics

Extremophiles

Mass spectrometry

Marine bacteria

Physiological and molecular responses of the marine oligotrophic ultramicrobacterium Sphingopyxis Alaskensis rb2256 to visible light and ultraviolet radiation

Matallana Surget, Sabine-Astrid, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Ultraviolet radiation reaching the Earth’s surface (UVR, 280-400 nm) may penetrate deep into the clear oligotrophic waters influencing a large part of the euphotic layer. Marine heterotrophic bacteria at the surface of the oceans are especially sensitive to the damaging solar radiation due to their haploid genome with little or no functional redundancy and lack of protective pigmentation. In a context of climate change and ozone depletion, it is clearly important to understand the physiology and underlying molecular UVR responses of abundant marine bacteria species. We chose the marine ultramicrobacterium Sphingopyxis alaskensis as a reference species to study the impact of solar radiation due to its numerical abundance in oligotrophic waters and its photoresistance, previously reported. For this purpose, we focused on the formation of the two major UVB-induced DNA photoproducts (CPDs and 6-4PPs) as well as the differential protein expression under solar radiation. We first demonstrated that the GC content of prokaryotic genome had a major effect on the formation of UVB-induced photoproducts, quantified by HPLC-MS/MS. Due to its high GC content, S. alaskensis presented a favoured formation of highly mutagenic cytosine-containing photoproducts and therefore would be more susceptible to UVinduced mutagenesis. By comparing S. alaskensis to another marine bacterium Photobacterium angustum, we observed for the latter strain a remarkable resistance to high UVB doses associated with a decrease in the rate of formation of CPDs explained by a non-conventional activity of photolyase. We also demonstrated that DNA damage in S. alaskensis was markedly modulated by growth temperature and time spent in stationary phase. In order to assess the effects that environmental UV-R had on regulatory networks and pathways of S. alaskensis, and determine how the cell’s physiology was affected, a quantitative proteomics investigation was performed. Changes in proteome were analyzed, with the recent and powerful mass spectrometry based approach using iTRAQ methodology. Approximately, one third of the proteome of S. alaskensis was identified, with 119 statistically and significantly differentially abundant proteins. Cellular processes, pathways and interaction networks were determined and gave us unique insight into the biology of UV response and adaptation of S. alaskensis.

Marine bacteria

UV radiation

Visible light

DNA damage

Proteomics

Cold adaptation in the Antarctic archeaon Methanococcoides burtonii: the role of the hydrophobic proteome and variations in cellular morphology

Burg, Dominic William, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Very little is known about the hydrophobic proteins of psychrophiles and their roles in cold adaptation. In light of this situation, methods were developed to analyse the hydrophobic proteome (HPP) of the model psychrophilic archaeon Methanococcoides burtonii. Central to this analysis was a novel differential solubility fractionation procedure, which resulted in a significant increase in the efficiency of resolving the HPP. Over 50% of the detected proteins were not identified in previous whole cell extract analyses, and these underwent an intensive manual annotation process producing high quality functional assignments. Utilising the functional assignments, biological context analysis of the HPP was performed, revealing novel and often unique biology. The analysis acted as a platform for differential proteomics of the organism???s response to both temperature and substrate using stable isotope labelling. The results of which revealed that low temperature growth was associated with an increase in the abundance of surface and secreted proteins, and translation apparatus. Conversely, growth at a higher temperature was associated with an increase in the abundance of general protein folding machinery and indications of an oxidative stress response, emphasising that the temperature for maximum growth rate is stressful. Through investigation of the response of M. burtonii to substrate it was found that growth on methanol was stressful, and its low energy yield resulted in an increase in the abundance of energy conserving systems. The extracellular polymeric substance (EPS) and morphology of M. burtonii was also investigated with respect to both temperature and substrate, using a number of techniques in microscopy. It was found that the EPS was comprised of proteins, sugars and RNA, and that growth at different temperatures resulted in the production of EPS that displayed significantly different properties on dehydration, thus indicating compositional variation. When cells were grown on methanol they took on highly irregular shapes and had electron transparent inclusions. The observations from the ultrastructural analysis were contemplated with respect to the proteomic findings, revealing novel avenues of research. This study has highlighted the roles of hydrophobic proteins in cold adaptation biology, and the value of comprehensive proteomics for the examination of adaptation in microorganisms

Cold adaptation

Hydrophobic proteome

Proteomics

Psychrophile

Differential solubility

iTRAQ

Morphometry

Functional characterization of the secretory pathway and the role of COPI vesicles /

Hiding, Johan,

January 2007

Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2007. / Härtill 3 uppsatser.

Novel data analysis methods and algorithms for identification of peptides and proteins by use of tandem mass spectrometry

Xu, Hua.

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Full text release at OhioLINK's ETD Center delayed at author's request

The germinal centre reaction : genetic and proteomic analysis of factors important for survival and growth of B lymphocytes /

Zander, Linda,

January 2008

Diss. (sammanfattning) Göteborg : Univ., 2008. / Härtill 4 uppsatser.

Proteomic strategies for analysis of cerebrospinal fluid in neurodegenerative disorders /

Hansson, Sara,

January 2008

Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2008. / Härtill 5 uppsatser.