Determination of analytes involved in red blood cell metabolism by employing microfluidics

D'Amico Oblak, Teresa.

January 2008

Thesis (PH. D.)--Michigan State University. Chemistry, 2008. / Title from PDF t.p. (viewed on Sept. 2, 2009) Includes bibliographical references. Also issued in print.

Metabolic biochemistry of freeze tolerance in vertebrates.

Churchill, Thomas Allen, Carleton University. Dissertation. Biology.

January 1992

Thesis (Ph. D.)--Carleton University, 1993. / Also available in electronic format on the Internet.

Intracellular hexokinase localization in hybridoma cultures implications for regulation of metabolism and cell death /

Clark, Lindsey M.

January 1900

Thesis (Ph. D. in Chemical Engineering)--Vanderbilt University, Aug. 2005. / Title from title screen. Includes bibliographical references.

Metabolic changes as potential biomarkers for assessing the mode of benzo[a]pyrene-induced cell death in human hepatoma (HepG₂) cells

Lin, Tao

01 January 2008

No description available.

Cell metabolism

Diseases

Environmental toxicology

Hepatotoxicology

Liver

Studies on phosphoglucomutase and phosphofructokinase from brain

Braun, Peter Eric

January 1964

It has recently been established that the activity of crystalline muscle phosphoglucomutase can be greatly stimulated by preincubation of the enzyme with a Mg++-imidazole complex. This observation has aroused interest in the physiological significance of such a system in the possible cellular control of phosphoglucomutase activity. The present study constitutes, in part, an investigation of the properties of phosphoglucomutase from brain tissue. A procedure for the purification of phosphoglucomutase from beef brain is described. The brain enzyme appears to be similar to that from skeletal muscle. Evidence is also presented which indicates that the "activation" produced by Mg++-imidazole is probably of no physiological importance in brain. This observation is consistent with the more recent reports that the phosphoglucomutase reaction is likely not involved in cellular regulatory mechanisms. It is well established that phosphofructokinase is intimately involved in the cellular regulation of glycolysis and the citric acid cycle. Control mechanisms of the phosphofructokinase reaction in mammalian tissues have been postulated on the basis of the complex kinetics of the enzyme. In yeast, however, two enzymatically interconvertible forms of the enzyme have been reported. Preliminary experiments in this study failed to demonstrate a phosphofructokinase system in brain similar to that found in yeast. / Medicine, Faculty of / Biochemistry and Molecular Biology, Department of / Graduate

Phosphoglucomutase

Phosphofructokinase

Neurochemistry

Brain

Cell metabolism

Investigating Metabolic Activities and Phenotypes in Biological Systems with Vibrational Probes and Raman Techniques

Zhao, Zhilun

January 2020

In this dissertation, the emerging stimulated Raman scattering (SRS) microscopy in combination with various vibrational tags was extensively used to explore various aspects of biological systems. New techniques as well as new Raman active materials were also developed to facilitate the applications of SRS in biology. Chapter one introduces and comprehensively reviews vibrational tags that have been developed to date in combination with imaging techniques and their applications in biological sciences to investigate metabolism in living organisms. Chapter two studies lipotoxicity, a phenomenon that is well known but poorly understood. The study found phase separation can form on ER membrane in cells treated with long chain fatty acids due to the high transition temptation of their metabolites. It was also found that the phase separation severely disturbs normal distribution of ER membrane proteins because of hydrophobic mismatching. As the result, ER normal structure is disrupted, luminal space is collapsed, and interconnectivity of ER that ensures normal ER functions is lost. Additionally, ER stress sensor IRE1α was found to be activated directly by the formation of phase separation, which triggers apoptosis and ultimately leads to cell death. Chapter three describes the development of a new method termed as metabolic activity phenotyping (MAP) that acquires quantitative measurements of metabolic activities of individual cells, which is essential to understanding questions in diverse fields in biology. To achieve the goal, an automatic system was designed and built that improves the acquisition speed by more than 100 times compared to commercially available instruments. A set of vibrational probes with deuterium labeling was also carefully selected to enable accurate measurement of metabolic flux. Combining the merits of high throughput measurements and vibrational tags, MAP was applied to investigate the metabolic activity differences among various cancer cells, to study the heterogeneity of drug efficacy, and to facilitate breast cancer subtyping. Chapter four describes the development and application of a new class of Raman active nanoparticles, or Rdots. These Rdots were generated by non-covalently incorporating small molecule Raman probe into polymeric nanoparticles. The resulted Rdots are of compact size (~20 nm) and preserve all Raman spectral features of the small molecule probes used. Rdots were compared to other existing Raman active materials including SERS nanoparticles, and Rdots surpass all the other materials in terms of brightness. In addition, Rdots also possess narrow spectral linewidth (< 3 nm), making them ideal for multiplexed imaging. In the study, Rdots were used as immunostaining reporters to visualize cytoskeleton networks and surface markers in cell and tissue samples.

Chemistry

Raman spectroscopy

Nanoparticles

Phenotype

Cell metabolism

Studies of insulin modulation of transcription in rat liver cells

Drake, Richard Lee

January 1975

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Insulin

Liver cells

Cell metabolism

Rats

Liver

ENGINEERING CO2-FIXING ESCHERICHIA COLI FOR HEXANOYL COENZYME A BIOSYNTHESIS THROUGH HETEROLOGOUS GENE EXPRESSION, GENE SILENCING AND TRANSCRIPTIONAL BIOCHEMICAL REPRESSION

Michael Rory Carlson (15354706)

04 June 2024

<p>  </p> <p>Sustainably produced oleochemicals from microbial lipid metabolism are an attractive alternative to traditional industrial production that is using expensive or non-renewable feedstocks. Though, microbial chassis as cell factories for production of oleochemicals at high titer for commercial exploitation require biochemical and genetic manipulation towards specific gene programming. As such, <em>Escherichia coli </em>cells are the laboratory workhorse with significant importance in biotechnological development and are the prime microbial candidate to drive synthesis of valuable compounds. The aim of this thesis is to demonstrate a novel metabolic system in <em>Escherichia coli</em> for controlled expression of specific genes encoding putative heterologous lipid-related enzymes and silencing native enzymes as wells as transcription factors to augment metabolic flow of specific pathways towards hexanoyl-CoA accumulation in the cell at commercial concentrations using a cheap feedstock. First, a CO2-fixing pathway was constructed in an <em>Escherichia coli</em> strain by introducing a donated expression cassette containing genes encoding two sequential cyanobacterial Calvin cycle enzymes; Rubisco (RBC)-encoding genes (<em>rbcL-rbcX-rbcS</em>), and phosphoribulokinase-encoding gene (<em>PRK</em>) and a cyanobacterial carbonic anhydrase (CA)-encoding genes (<em>ccaA</em>), mimicking cyanobacterial carbon concentrating mechanism. Second, a hexanoyl-CoA-producing pathway was incorporated by including an <em>Arabidopsis thaliana</em> acyl-lipid thioesterase 4-encoding gene (<em>ALT4</em>) and acyl-activating enzyme-encoding gene (<em>AAE17</em>). Next, an antisense RNA pathway was incorporated into the previously engineered strain to prevent the flow of the produced hexanoyl-CoA to β-oxidation and phospholipid synthesis. Three RNA-silencing sequences targeting <em>Escherichia coli </em>anaerobic acyl-CoA dehydrogenase-encoding gene (<em>Ydio</em>), aerobic acyl-CoA dehydrogenase-encoding gene (<em>FadE</em>) and fused 2-acylglycerophospho-ethanolamine acyltransferase/acyl-acyl carrier protein synthetase-encoding gene (<em>aas</em>) were incorporated. Finally, DNA-binding transcriptional dual regulator-encoding gene (<em>FadR</em>) targeting β-oxidation repression was incorporated. Markedly, the engineered <em>Escherichia coli</em> productivity of hexanoyl‑CoA was 100% increase over wildtype. This multi-gene transformation system is the first report in increasing hexanoyl-CoA through controlling simultaneously fatty acid biosynthesis and β-oxidation, utilizing simple RNA silencing and transcriptional repression technology in <em>Escherichia coli</em> cells. <br>  </p>

Cell metabolism

Molecular Biology

Biochemistry

Bacterial engineering

Metabolic reprogramming of T cells to optimize adoptive T cell therapy

Waller, Alexandra

18 June 2019

The clinical efficacy of adoptive T cell therapies including CAR T therapy are limited by poor in vivo persistence and moderate anti-tumor efficacy. According to the literature, metabolism plays a critical role in the phenotypic state and fate of T cells during antigen-driven expansion. During different stages of a T cell life cycle, the predominant pathway used for metabolism changes. Naïve T rely on oxidative phosphorylation, but as the T cells becomes activated, their metabolic profile switches to become more reliant on glycolysis. Most T cells become terminally differentiated and become senescent once they have performed their cytotoxic function. A minority of the activated T cells gradually start to rely on oxidative phosphorylation once again and become memory T cells. Memory T cells can become either effector memory or central memory T cells. These memory T cells, specifically central memory T cells, are the key to T cells persistence during both ex vivo and in vivo expansion and following disappearance of the antigenic stimulus. Since the metabolic profile of the T cells plays a critical role in its differentiation state, we tested the hypothesis that inhibitors of intermediary metabolism could promote a metabolic profile that is more desirable for the optimal phenotype consistent with the memory phenotype that would favor persistence in spite of strong activation signals. The four inhibitors screened were: a PFKFB3 inhibitor, an inhibitor of a key step in glycolysis; ibrutinib, an inhibitor of Bruton’s tyrosine kinase; idelalisib, an inhibitor of PI3K subunit; and duvelisib, an inhibitor of PI3K and PI3K gamma subunits. To test this hypothesis, T cells were cultured with or without each compound and then the analysis included: phenotypic analysis by flow cytometry, quantitative analysis by counting cells with ethidium bromide acridine orange, and metabolic profiling by the Seahorse assay. This study was conducted using T cells from a human healthy volunteer that were collected by apheresis. T cells were cultured in a G-Rex plate for 15 days with complete media supplemented with recombinant human IL-2 (30 U/mL). Cells were activated on day 1 and day 8 by the addition of anti-CD3/CD28 beads and test metabolic inhibitor compounds were added every 4 days. T cells cultured with idelalisib, duvelisib, and ibrutinib had increased expansion (approximately50-fold: idelalisib/ duvelisib and 21-fold ibrutinib) when compared to control (cells with beads alone) with only 6-fold expansion. Phenotypic analysis performed using flow cytometry showed an increased percentage of CD27+ CD28+ in the CD8+ and CD4+ T cell cell populations in the idelalisib treated group and decreased number of senescent T cells that are double negative for CD27 and CD28. Consistent with our hypothesis, metabolic analysis showed that cells treated with idelalisib and duvelisib were more reliant on oxidative phosphorylation, rather than glycolysis as compared to the control cultures. Cells treated with duvelisib also showed an increased spare respiratory capacity (SRC), which is associated with more efficacious memory T cells. The results of these studies show that metabolism plays a critical role in the long-term survival of T cells. We demonstrate that inhibiting intermediary metabolism, specifically inhibiting PI3K, favorably alters the metabolic state of the T cells leading to increased cell numbers and T cells with a phenotype consistent with enhanced ex vivo and in vivo proliferation and persistence.

Immunology

Spare respiratory capacity

T cell

T cell metabolism

Effect of cellular redox and energy states on benzo[a]pyrene induced modes of death in the hepa and the HepG2 cell lines

To, Wing Shu

01 January 2010

No description available.

Benzopyrene

Cell death

Cell metabolism

Liver cells

Research