The fatty acyl composition of phospholipids determines the biophysical character of membranes and impacts the function of membrane proteins. Here we define a nuclear receptor pathway for the dynamic modulation of membrane composition in response to changes in cellular lipid metabolism. Ligand activation of LXR preferentially drives the incorporation of polyunsaturated fatty acids into phospholipids through induction of the remodeling enzyme Lpcat3. Promotion of Lpcat3 activity ameliorates ER stress induced by saturated free fatty acids in vitro or by obesity and hepatic lipid accumulation in vivo. Conversely, Lpcat3 knockdown in liver exacerbates ER stress and inflammation. Mechanistically, Lpcat3 modulates inflammation both by regulating c-Src and JNK kinase activation through changes in membrane composition and by affecting substrate availability for inflammatory mediator production. These results outline an endogenous mechanism for the preservation of membrane homeostasis during lipid stress and identify Lpcat3 as an important mediator of LXRs effects on metabolism.
SREBPs are key transcriptional regulators of lipid metabolism and cellular growth. It has been proposed that SREBP signaling regulates cellular growth through its ability to drive lipid biosynthesis. Unexpectedly, we find that loss of SREBP activity inhibits cancer cell growth and viability by uncoupling fatty acid synthesis from desaturation. Integrated lipid profiling and metabolic flux analysis revealed that cancer cells with attenuated SREBP activity maintain long-chain saturated fatty acid synthesis, while losing fatty acid desaturation capacity. We traced this defect to the uncoupling of Fatty Acid Synthase activity from SCD1-mediated desaturation. This deficiency in desaturation drives an imbalance between the saturated and monounsaturated fatty acid pools resulting in severe lipotoxicity. Importantly, replenishing the monounsaturated fatty acid pool restored growth to SREBP-inhibited cells. These studies highlight the importance of fatty acid desaturation in cancer growth and provide a novel mechanistic explanation for the role of SREBPs in cancer metabolism.
Significance
Bacterial and viral infections are a significant public health burden. To corrupt normal host cellular functions, many bacterial toxins and all viruses must gain entry to host cells, a process that exploits the host’s own cellular machinery. In this study, we use high-throughput technologies to screen for chemical inhibitors of bacterial toxin and viral entry. We report the discovery of a small molecule that inhibits several viruses and bacterial toxins. In addition to the therapeutic potential, this compound represents a powerful probe for dissecting the mechanisms of mammalian membrane trafficking processes.
Kinetics
studies of dNTP analogues having pyrophosphate-mimicking
β,γ-pCXYp leaving groups with variable X and Y substitution
reveal striking differences in the chemical transition-state energy
for DNA polymerase β that depend on all aspects of base-pairing
configurations, including whether the incoming dNTP is a purine or
pyrimidine and if base-pairings are right (T•A and G•C)
or wrong (T•G and G•T). Brønsted plots of the catalytic
rate constant (log(kpol)) versus pKa4 for the leaving group exhibit linear free
energy relationships (LFERs) with negative slopes ranging from −0.6
to −2.0, consistent with chemical rate-determining transition-states
in which the active-site adjusts to charge-stabilization demand during
chemistry depending on base-pair configuration. The Brønsted
slopes as well as the intercepts differ dramatically and provide the
first direct evidence that dNTP base recognition by the enzyme–primer–template
complex triggers a conformational change in the catalytic region of
the active-site that significantly modifies the rate-determining chemical
step.
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