Co-immunoprecipitation analysis of the phosphoenolpyruvate carboxylase interactome of developing castor oil seeds

Uhrig, Richard Glen

09 January 2008

Co-immunoprecipitation (co-IP) followed by proteomic analysis was employed to examine the phosphoenolpyruvate carboxylase (PEPC) interactome of developing castor oil seed (COS) endosperm. Earlier studies suggested that immunologically unrelated 107-kDa plant-type and 118-kDa bacterial-type PEPCs (p107/PTPC and p118/BTPC, respectively) are subunits of an unusual ~910-kDa hetero-octameric Class-2 PEPC complex of developing COS. The current results confirm that a tight physical interaction occurs between p118 and p107 since p118 quantitatively co-IP’d with p107 following elution of COS extracts through an anti-p107-IgG immunoaffinity column. No PEPC activity or immunoreactive PTPC or BTPC polypeptides were detected in the corresponding flow-through fractions. Although BTPCs lack the N-terminal phosphorylation site characteristic of PTPCs, Pro-Q Diamond Phosphoprotein staining, immunoblotting with phospho-(Ser/Thr) Akt substrate IgG, and phosphate-affinity PAGE demonstrated that the co-IP’d p118 was significantly phosphorylated at unique Ser and/or Thr residue(s). The co-IP of p118 and p107 was not influenced by their phosphorylation status. As p118 phosphorylation appeared unchanged 48 h following elimination of photosynthate supply due to COS depodding, the signaling mechanisms responsible for photosynthate-dependent p107 phosphorylation differ from those controlling p118’s in vivo phosphorylation. A third PEPC polypeptide of ~110-kDa (p110; RcPPC1) co-IP’d with p118 and p107 when depodded COS was used. Analysis of RcPpc1’s full-length cDNA sequence revealed p110’s identity with PTPCs, but that a pair of unique amino-acid substitutions occurs in its N-terminal sequence that may render p110 non-phosphorylatable in vivo. The plastidial pyruvate dehydrogenase complex (PDCpl) was identified as a novel PEPC interactor. Subcellular fractionation indicated that p118 and p107 are strictly cytosolic, but that PDCpl is targeted to both the cytosol and leucoplast of developing COS. Thus, a putative cytosolic metabolon involving PEPC and PDCpl could function to channel carbon from phosphoenolpyruvate to acetyl-CoA and/or to recycle CO2 from PDCpl to PEPC. / Thesis (Master, Biology) -- Queen's University, 2007-09-26 15:57:52.216

PEPC

Co-IP

Fatty acid synthesis

Proteomics

Proteomic analysis of heart failure : insights into myofibril assembly and regulation

Stanley, Brian Allan

09 January 2008

Heart failure (HF) is a prevalent disease in society which is associated with decreased cardiac output. This thesis describes the proteomic analysis of cardiac tissue obtained from HF patients and a transgenic animal model of HF. Initial experiments optimized one proteomic technology, 2-dimensional gel electrophoresis (2-DE), to maximize the number of proteins which could be observed / resolved from human cardiac tissue. Protein abundance changes in cardiac tissue between normal patients and those with a diagnosis of ischemic cardiomyopathy were determined by performing 2-DE and identifying proteins by mass spectrometry. HF patients had a reduced abundance of proteins involved in energy production and the sarcomere. Sarcomeres contain the myofilament subproteome consisting of thick and thin filaments with the thick filaments primarily myosin. Thick and thin filament undergo Ca2+ induced ATP hydrolysis to form crossbridge cycles, resulting in muscle contraction. An assembly chaperone for myosin, UNC-45B, was found to be increased in HF patients. Western blot analysis confirmed that the abundance of UNC-45B was increased in different etiologies of heart failure. Follow up physiological measurements demonstrated that UNC-45B is most likely a protein necessary for transcriptional control of the α-isoform of myosin heavy chain. In a second proteomics study, abundance changes occurring in a pacing induced model of HF in wild-type (WT) and transgenic (TG) rabbits with increased expression of the α-isoform of myosin heavy chain were examined. WT and TG rabbits had a different response in their myofilament and intermediate filament abundance changes following induction of HF. TG rabbits had a decreased abundance of heat shock proteins and non-sarcomeric associated desmin. As well, TG rabbits had an increased ratio of actin:myosin heavy chain and UNC-45B suggesting an altered ratio of thick to thin filaments. In conclusion, an altered abundance of contractile proteins, regulated in part by UNC-45B, may be one cause of the contractile dysfunction which occurs in HF. / Thesis (Ph.D, Physiology) -- Queen's University, 2007-12-21 09:19:45.172

Proteomics

Heart failure

Human

Transgenic rabbits

Itch E3 ubiquitin ligase regulates LATS1 tumour suppressor stability

Ho, King Ching

27 April 2011

The Large Tumor Suppressor 1 (LATS1) is a serine/threonine kinase and tumor suppressor found down-regulated in a broad spectrum of human cancers. It is a central player of the emerging Hippo-LATS tumour suppressor pathway, which plays important roles in cell proliferation, apoptosis, and stem cell differentiation. Despite the ample data supporting a role of LATS1 in tumour suppression, how LATS1 is regulated at the molecular level remains largely unknown. In this study, we have identified Itch, a HECT class E3 ubiquitin ligase, as a novel binding partner of LATS1. Itch can complex with LATS1 both in vitro and in vivo through the PPxY motifs of LATS1 and the WW domains of Itch. Significantly, we found that over-expression of Itch promoted LATS1 degradation by polyubiquitination through the 26S proteasome pathway. On the other hand, knockdown of endogenous Itch by shRNAs provoked stabilization of endogenous LATS1 proteins. Finally, through several functional assays, we also revealed that change of Itch abundance alone is sufficient for altering LATS1-mediated downstream signaling, negative regulation of cell proliferation, and induction of apoptosis. Together, our study identifies E3 ubiquitin ligase Itch as the first negative regulator of LATS1 and presents for the first time a possibility of targeting LATS1/Itch interaction as a therapeutic strategy in cancer. / Thesis (Master, Pathology & Molecular Medicine) -- Queen's University, 2011-04-26 22:25:46.008

Proteomics

Ubiquitination

Tumour suppressor

Protein stability

A proteome-level analysis of the canola/Sclerotinia sclerotiorum interaction and sclerotial development

Liang, Yue

Unknown Date

No description available.

canola

proteomics

sclerotia

Sclerotinia sclerotiorum

stem rot

Proteomic analysis of wheat (Triticum aestivum) whole roots and cell walls under water-deficit stress

Ganesh, Shiv

Unknown Date

No description available.

Proteomics

Wheat

Water-deficit

Stress

Plant

Development and Applications of Stable Isotope Labelling Liquid Chromatography Mass Spectrometry for Quantitative Proteomics

Lo, Andy

Unknown Date

No description available.

proteomics

mass spectrometry

isotope labelling

quantitation

Proteomics and metabolism of the mesophilic cellulolytic bacterium, Clostridium termitidis strain CT1112

Ramachandran, Umesh

05 November 2008

Consolidated bioprocessing, a method that involves cellulase production, substrate hydrolysis, and fermentation all in one step, requires lower energy input and aims at achieving reduced biofuel production costs than traditional processes. It is an economically appealing strategy for the efficient production of biofuels such as ethanol or H2. At present, the yields of fermentative hydrogen and ethanol production are less than the theoretical maximum and vary between anaerobic Clostridia due to the presence of highly branched metabolic pathways. With the recent advancements in ‘Omic technologies, the selected cellulolytic species, in this case, C. termitidis, was extensively studied to identify the key enzymes that are involved in hydrogen and ethanol synthesis pathways in both the genome and proteome under different culture conditions. Metabolic characterization involving growth and end-product synthesis patterns were performed on 2 g L-1 cellobiose and α-cellulose under batch conditions to determine its metabolic potential for hydrogen and/or ethanol production. Initial characterization has shown the ability of C. termitidis to produce hydrogen, ethanol, and various other end-products on the two susbtrates. Continous N2 sparging in the pH-controlled bioreactors with cellobiose and α-cellulose showed a consistent increase in the H2 synthesis and lowered ethanol production compared to batch studies, with the H2 yields of 1.03 and 1.34 mol product per mol hexose equivalent added, respectively. Shotgun 2-D proteome analyses were performed to compare cellulose versus cellobiose grown cultures across exponential and stationary phases of growth. Most of the glycolytic proteins were detected in the proteome with some exceptions and no significant change was observed across both growth conditions. Hydrogen synthesis was regulatd via PFOR and ferredoxin-dependent hydrogenase, where as ethanol synthesis was regulated primarily via bifunctional AdhE activity. Proteomic analyses of C. termitidis cultured on hexose sugars in the absence of xylose suggested possible sequential utilization of xylose and cellobiose for the first time. Putative proteins consistent with xylose fermentation were observed at high levels. The hypothesis that C. termitidis can sequentially utilize xylose and cellobiose was further validated using batch fermentations tests on pure (xylose, cellobiose, xylan) and mixed substrates (xylose + cellobiose).

Biofuels

Cellulolytic Clostridia

Metabolism

Proteomics

Hydrogen

Ethanol

Identification and Validation of Candidate Breast Cancer Biomarkers: A Mass Spectrometric Approach

Kulasingam, Vathany

17 April 2012

One of the best ways to diagnose breast cancer early or to predict therapeutic response is to use serum biomarkers. Unfortunately, for breast cancer, we do not have effective serological biomarkers. We hypothesized that novel candidate tumor markers for breast cancer may be secreted or shed proteins that can be detected in tissue culture supernatants of human breast cancer cell lines. A two-dimensional liquid chromatography-tandem mass spectrometry (2D-LC-MS/MS) strategy was utilized to identify and compare levels of extracellular and membrane-bound proteins in the conditioned media. Proteomic analysis of the media identified in excess of 600, 500 and 700 proteins in MCF-10A, BT474 and MDA-MB-468, respectively. We successfully identified the internal control proteins, kallikreins 5, 6 and 10 (ranging in concentration from 2-50 µg/L), as validated by ELISA and confidently identified HER-2/neu in BT474 cells. Sub-cellular localization was determined based on Genome Ontology (GO) for the 1,139 proteins, of which 34% were classified as extracellular and membrane-bound. Tissue specificity, functional classifications and label-free quantification were performed. The levels of eleven promising molecules were measured in biological samples to determine its discriminatory ability for control versus cases. This screen yielded activated leukocyte cell adhesion molecule (ALCAM) as a promising candidate. The levels of ALCAM, in addition to the classical breast cancer tumor markers carbohydrate antigen 15-3 (CA 15-3) and carcinoembryonic antigen (CEA) were examined in 300 serum samples by quantitative ELISA. All three biomarkers effectively separated cancer from non-cancer groups. ALCAM, with area under the curve (AUC) of 0.78 [95% CI: 0.73, 0.84] outperformed CA15-3 (AUC= 0.70 [95% CI: 0.64, 0.76]) and CEA (AUC= 0.63 [95% CI: 0.56, 0.70]). The incremental values of AUC for ALCAM over that for CA15-3 were statistically significant (Delong test, p <0.05). Serum ALCAM appears to be a new biomarker for breast cancer and may have value for disease diagnosis.

proteomics

mass spectrometry

breast cancer

diagnostics

0992

Analyzing the properties and biosynthesis of β-glucans from Gluconacetobacter and poplar

Malm, Erik

January 2014

Glucans are polysaccharides integral to many materials and biological functions. Under the umbrella of Biomime, the Swedish Center for Biomimetic Fiber Engineering, this work has aimed to improve basic understanding of the biosynthesis of such glucans. This has been achieved through direct investigation of cellulose structure, and by developing the tools to analyze glucan biosynthesis. Notably we have identified a novel chemical effector of glucan synthesis processes and developed a proteomic toolkit useful for analyzing membrane-bound glycosyltransferases, the enzyme group responsible for glucan biosynthesis. During this work, glucan synthesis has been studied using both Gluconacetobacter and Populus cell suspension cultures. Publication I. Gluconacetobacter cellulose (BC) was used as a base to create a novel and well characterized nano-material with improved mechanical properties. This novel composite of BC and hydroxyethylcellulose (HEC) had improved tensile strength compared to pure BC. Through thorough study utilizing dispersion measurements, electron microscopy, nuclear magnetic resonance and X-ray diffraction it was shown that the improved properties derived from a layer of HEC coating each fibril. Publication II. Bacterial cellulose was labeled in specific positions with 13C (C4 and C6). These samples were analyzed by CP/MAS NMR along with cellulose samples from cotton and Halocynthia sp. For each sample spectral fitting was performed and general properties of crystal allomorph composition and fibril widths were determined. Calculations were also made for water accessible surfaces of the fibrils. The results showed that water accessible C4 surface signals are reflective of the allomorph composition of the sample, along with a distorted signal that derives due to fibril imperfections. Water accessible surface signals from the C6 region are instead derived from rotamer conformations of the C6 hydroxymethyl groupsfrom glucose residues. In Publication III, a high-throughput screen was used to identify an inhibitor of Golgi-derived glycosyltransferase activity, termed chemical A. The structural basis for inhibition was determined and in vitro assays of callose synthesis were performed. The in vitro assays revealed chemical A to also be an activator of callose synthesis. To understand this activation kinetic studies were performed, showing that chemical A is a mixed type of activator, which can bind either the free enzyme or the enzyme-substrate complex. Chemical A has uses in chemical genetics for dissecting processes involving callose synthesis, such as stress response and cell-plate formation. In publication IV, we present an in-house developed platform for proteomics with a distributed processing model. This in-house system has been central to many proteomics tasks, including for those presented in publication V, and is being distributed as the Automated Proteomics Pipeline (APP). In publication V, conditions for enrichment of Detergent-Resistant Microdomains (DRM) have been optimized for Populus trichocarpa cell cultures. The proteins enriched in DRM were identified using mass spectrometry based proteomics, and a functional model for DRM was proposed. This model involves proteins specialized in stress response, including callose synthase, and cell signaling. This further strengthens the arguments for DRMs as sites of specific cellular functions and confirms they play a role in glucan synthesis. / <p>QC 20140710</p>

Cellulose synthesis

Bioinformatics

Proteomics

Cell wall

Proteomics and metabolism of the mesophilic cellulolytic bacterium, Clostridium termitidis strain CT1112

Ramachandran, Umesh

05 November 2008

Consolidated bioprocessing, a method that involves cellulase production, substrate hydrolysis, and fermentation all in one step, requires lower energy input and aims at achieving reduced biofuel production costs than traditional processes. It is an economically appealing strategy for the efficient production of biofuels such as ethanol or H2. At present, the yields of fermentative hydrogen and ethanol production are less than the theoretical maximum and vary between anaerobic Clostridia due to the presence of highly branched metabolic pathways. With the recent advancements in ‘Omic technologies, the selected cellulolytic species, in this case, C. termitidis, was extensively studied to identify the key enzymes that are involved in hydrogen and ethanol synthesis pathways in both the genome and proteome under different culture conditions. Metabolic characterization involving growth and end-product synthesis patterns were performed on 2 g L-1 cellobiose and α-cellulose under batch conditions to determine its metabolic potential for hydrogen and/or ethanol production. Initial characterization has shown the ability of C. termitidis to produce hydrogen, ethanol, and various other end-products on the two susbtrates. Continous N2 sparging in the pH-controlled bioreactors with cellobiose and α-cellulose showed a consistent increase in the H2 synthesis and lowered ethanol production compared to batch studies, with the H2 yields of 1.03 and 1.34 mol product per mol hexose equivalent added, respectively. Shotgun 2-D proteome analyses were performed to compare cellulose versus cellobiose grown cultures across exponential and stationary phases of growth. Most of the glycolytic proteins were detected in the proteome with some exceptions and no significant change was observed across both growth conditions. Hydrogen synthesis was regulatd via PFOR and ferredoxin-dependent hydrogenase, where as ethanol synthesis was regulated primarily via bifunctional AdhE activity. Proteomic analyses of C. termitidis cultured on hexose sugars in the absence of xylose suggested possible sequential utilization of xylose and cellobiose for the first time. Putative proteins consistent with xylose fermentation were observed at high levels. The hypothesis that C. termitidis can sequentially utilize xylose and cellobiose was further validated using batch fermentations tests on pure (xylose, cellobiose, xylan) and mixed substrates (xylose + cellobiose).

Biofuels

Cellulolytic Clostridia

Metabolism

Proteomics

Hydrogen

Ethanol