Our findings that PlGF is a cancer target and anti-PlGF is useful for anticancer treatment have been challenged by Bais et al. Here we take advantage of carcinogen-induced and transgenic tumor models as well as ocular neovascularization to report further evidence in support of our original findings of PlGF as a promising target for anticancer therapies. We present evidence for the efficacy of additional anti-PlGF antibodies and their ability to phenocopy genetic deficiency or silencing of PlGF in cancer and ocular disease but also show that not all anti-PlGF antibodies are effective. We also provide additional evidence for the specificity of our anti-PlGF antibody and experiments to suggest that anti-PlGF treatment will not be effective for all tumors and why. Further, we show that PlGF blockage inhibits vessel abnormalization rather than density in certain tumors while enhancing VEGF-targeted inhibition in ocular disease. Our findings warrant further testing of anti-PlGF therapies.
In the original article, the surname of co-author Wouter Everaerts was spelled incorrectly as "Everaert." It appears correctly in this Correction, and the error has been corrected online.
Summary
Neutrophils can function and survive in injured and infected tissues, where oxygen and metabolic substrates are limited. Using radioactive flux assays and LC-MS tracing with U-
13
C glucose, glutamine, and pyruvate, we observe that neutrophils require the generation of intracellular glycogen stores by gluconeogenesis and glycogenesis for effective survival and bacterial killing. These metabolic adaptations are dynamic, with net increases in glycogen stores observed following LPS challenge or altitude-induced hypoxia. Neutrophils from patients with chronic obstructive pulmonary disease have reduced glycogen cycling, resulting in impaired function. Metabolic specialization of neutrophils may therefore underpin disease pathology and allow selective therapeutic targeting.
Muscle regeneration is sustained by infiltrating macrophages and consequent satellite cell (SC) activation
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. Macrophages and SC communicate in different ways
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but their metabolic interplay was never investigated so far. Here, we found that muscle injuries and aging are characterized by intratissutal glutamine restriction. Low glutamine levels endow macrophages with the metabolic ability to secrete glutamine via enhanced glutamine synthetase (GS) activity at the expense of glutamate dehydrogenase-1 (GLUD1)-mediated glutamine oxidation.
Glud1
knockout (KO) macrophages display constitutively high GS activity which prevents glutamine shortage. Import of macrophage-derived glutamine by SC through the glutamine-transporter SLC1A5 activates mTOR and promotes SC proliferation and differentiation. Consequently, macrophage-specific deletion or pharmacological inhibition of GLUD1 improves muscle regeneration and functional recovery in response to acute injury, ischemia, or aging. Conversely, SLC1A5 blockade in SC or GS inactivation in macrophages negatively affects SC functions and muscle regeneration. These results highlight a metabolic cross-talk between SC and macrophages whereby macrophage-derived glutamine sustains SC functions. Thus, GLUD1 targeting offers new therapeutic opportunities for the regeneration of injured or aged muscles.
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