<p>It has been long known that many types of cancers have high metabolic requirements and use reprogrammed metabolism to support cellular activities. The first identified metabolic alteration in cancer cells was elevated glucose uptake, glycolysis activity and lactate production even in the presence of oxygen. This metabolic program, termed aerobic glycolysis or the Warburg effect, provides cells with energy as well as biosynthetic substrates to sustain cell survival and rapid cell proliferation. Cancer metabolism is closely linked to genetic mutations and oncogenic signaling pathways, such as PI3K/Akt, cMyc and HIF pathways. These oncogenic signals can direct metabolic reprogramming while changes in metabolic status can regulate activities of these signaling pathways in turn. In addition to glucose, later studies also found utilization of alternate nutrients in cancer cells, including glutamine and lipids. Glutamine is the second major metabolic fuel and can be converted to various substrates to support cell bioenergetics needs and biosynthetic reactions. Usage of metabolic fuels in cancer cells, however, is variable. While certain cancers display addiction to one type of nutrient, others are capable of using multiple nutrients. </p><p>The unique metabolic features of cancer cells raise the possibility of targeting metabolism as a novel therapeutic approach for cancer treatment. Using pharmacological inhibitors, previous research has provided corroborating evidence that metabolic stress can impact survival and growth of proliferative cancer cells by regulating cell apoptotic machinery and cell cycle checkpoints. Due to lack of genetic tools and side effects from these inhibitors, however, mechanistic understanding of cell response to metabolic inhibition was limited in these studies. More importantly, how metabolic stress affects cancer progression in a physiological condition has not yet been well investigated. Lastly, current research has not examined metabolic program in indolent cancers and the metabolic requirements and activities in less proliferative cells also remain to be understood.</p><p>This work examines nutrients utilization in B cell derived acute and chronic leukemia (B-ALL and B-CLL). B-ALL is an aggressive form of leukemia. Using cell lines and primary patient samples, we found B-ALL cells primarily used glucose through aerobic glycolysis, similar to other proliferative cancer cells. B-ALL cells were also more sensitive to inhibition of glycolysis than normal B cells. Employing an untargeted metabolomics profiling in combination with isotope labeled glucose tracing approach, we show in a B-ALL model that genetic ablation of glucose transporter Glut1 partially reduced glucose uptake, sufficiently hindered anabolic pathways and promoted catabolic metabolism. This metabolic shift led to sharply curtailed B-ALL proliferation in vitro and reduced leukemic burden in vivo. Furthermore, this partial inhibition of glucose metabolism sensitized B-ALL cells to apoptotic stimuli and non-cytotoxic metabolic inhibition significantly enhanced efficacy of a tyrosine kinase inhibitor to eliminate B-ALL cells in vitro and in vivo. Thus, partial inhibition of glucose metabolism can provide a plausible adjuvant therapy to treat cancers that depend on glycolysis for survival and proliferation. </p><p>In contrast to B-ALL, B-CLL is an indolent form of cancer. Most B-CLL cells exhibited low glucose metabolic activities that were comparable with normal B cells at resting stage. Similar to chronically stimulated and anergic B cells, these B-CLL cells also failed to upregulate glucose metabolism in response to IgM stimulation. We also observed an altered amino acid and acyl-carnitine profile and increased glutaminase mRNA in B-CLL relative to normal B cells, suggesting the capability of using alternate nutrients such as glutamine in these cells. Finally, we explored the possibility of suppressing mitochondria metabolism to induce B-CLL cell death through inhibition of the nuclear hormone receptor and metabolic regulator ERRalpha. ERRalpha is known to regulate mitochondrial metabolism and was expressed higher in B-CLL than normal B cells. ERRalpha inhibition decreased viability of oncogene transformed pro-B cells, suggesting ERRalpha as a potential target for B-CLL treatment.</p><p> Collectively, this work investigates metabolic phenotype in two forms of leukemia derived from B cells. It reveals different metabolic requirements and activities in aggressive and indolent leukemia and explores different approaches to suppress metabolism in these cancers. Findings of this work shed light on how to potentially design metabolic approach to improve cancer treatment.</p> / Dissertation
Identifer | oai:union.ndltd.org:DUKE/oai:dukespace.lib.duke.edu:10161/9410 |
Date | January 2014 |
Creators | Liu, Tingyu |
Contributors | Rathmell, Jeffrey C |
Source Sets | Duke University |
Detected Language | English |
Type | Dissertation |
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