Glucose Oxidase-Instructed Traceable Self-Oxygenation/Hyperthermia Dually Enhanced Cancer Starvation Therapy.

Cancer theranostics based on glucose oxidase (GOx)-induced starvation therapy has got more and more attention in cancer management. Herein, GOx armed manganese dioxide nanosheets (denoted as MNS-GOx) were developed as cancer nanotheranostic agent for magnetic resonance (MR)/photoacoustic (PA) dual-modal imaging guided self-oxygenation/hyperthermia dually enhanced starvation cancer therapy. The manganese dioxide nanomaterials with different morphologies (such as nanoflowers, nanosheets and nanowires) were synthesized by a biomimetic approach using melanin as a biotemplate. Afterwards, the manganese dioxide nanosheets (MNS) with two sides and large surface area were selected as the vehicle to carry and deliver GOx. The as-prepared MNS-GOx can perform the circular reaction of glucose oxidation and H2O2 decomposition for enhanced starvation therapy. Moreover, the catalytic activity of GOx could be further improved by the hyperthermia of MNS-GOx upon near-infrared laser irradiation. Most intriguingly, MNS-GOx could achieve "turn-on" MR imaging and "turn-off" PA imaging simultaneously. The theranostic capability of MNS-GOx was evaluated on A375 tumor-bearing mice with all tumor elimination. Our findings integrated molecular imaging and starvation-based synergistic cancer therapy, which provided a new platform for cancer nanotheranostics.

Starvation tactics using natural compounds for advanced cancers: pharmacodynamics, clinical efficacy, and predictive biomarkers.

The high mortality associated with oncological diseases is mostly due to tumors in advanced stages, and their management is a major challenge in modern oncology. Angiogenesis is a defined hallmark of cancer and predisposes to metastatic invasion and dissemination and is therefore an important druggable target for cancer drug discovery. Recently, because of drug resistance and poor prognosis, new anticancer drugs from natural sources targeting tumor vessels have attracted more attention and have been used in several randomized and controlled clinical trials as therapeutic options. Here, we outline and discuss potential natural compounds as salvage treatment for advanced cancers from recent and ongoing clinical trials and real-world studies. We also discuss predictive biomarkers for patients' selection to optimize the use of these potential anticancer drugs.

Metabolism of inflammation limited by AMPK and pseudo-starvation.

Metabolic changes in cells that participate in inflammation, such as activated macrophages and T-helper 17 cells, include a shift towards enhanced glucose uptake, glycolysis and increased activity of the pentose phosphate pathway. Opposing roles in these changes for hypoxia-inducible factor 1α and AMP-activated protein kinase have been proposed. By contrast, anti-inflammatory cells, such as M2 macrophages, regulatory T cells and quiescent memory T cells, have lower glycolytic rates and higher levels of oxidative metabolism. Some anti-inflammatory agents might act by inducing, through activation of AMP-activated protein kinase, a state akin to pseudo-starvation. Altered metabolism may thus participate in the signal-directed programs that promote or inhibit inflammation.

Starving tumors: inhibition of glycolysis reduces viability of human endometrial and ovarian cancer cells and enhances antitumor efficacy of GnRH receptor-targeted therapies.

OBJECTIVE: Increased glycolysis for energy production is necessary for survival of tumor cells and thus represents a selective therapeutic target. We have analyzed in vitro whether inhibition of glycolysis can reduce the viability of human endometrial and ovarian cancer cells and whether it can enhance the antitumor efficacy of GnRH receptor-targeted therapies. MATERIALS AND METHODS: Cell viability of ovarian and endometrial cancer cells treated without or with glycolysis inhibitor 2-Deoxy-D-Glucose (2DG) alone or in combination with GnRH-II antagonist [Ac-D2Nal(1), D-4Cpa(2), D-3Pal(3,6)(8),Leu, D-Ala(10)]GnRH-II or with cytotoxic GnRH-I agonist AEZS-108 (AN-152) was measured using alamar blue assay. Induction of apoptosis was analyzed using TUNEL assay and quantified by measurement of loss of mitochondrial membrane potential. Apoptotic signaling was measured by quantification of activated caspase-3 by using the Western blot technique. RESULTS: Treatment of endometrial and ovarian cancer cells with glycolysis inhibitor 2DG resulted in a significant decrease of cell viability and a significant increase of apoptosis. Treatment with 2DG in combination with the GnRH-II antagonist or with AEZS-108 resulted in a significant reduced viability compared with single-agent treatments. The observed reduction in viability was due to induction of apoptosis. Also for apoptosis induction, a significant stronger effect in the case of cotreatments compared with single-agent treatments could be observed. These additive effects could be correlated to increased activation of caspase-3. CONCLUSIONS: The glycolytic phenotype of human endometrial and ovarian cancer cells can be targeted for therapeutic intervention. In addition, cotreatment of a glycolysis inhibitor with GnRH receptor-targeted therapies might be a suitable therapy for GnRH receptor-positive human endometrial and ovarian cancers.

Multiple TORC1-associated proteins regulate nitrogen starvation-dependent cellular differentiation in Saccharomyces cerevisiae.

BACKGROUND: The budding yeast Saccharomyces cerevisiae undergoes differentiation into filamentous-like forms and invades the growth medium as a foraging response to nutrient and environmental stresses. These developmental responses are under the downstream control of effectors regulated by the cAMP/PKA and MAPK pathways. However, the upstream sensors and signals that induce filamentous growth through these signaling pathways are not fully understood. Herein, through a biochemical purification of the yeast TORC1 (Target of Rapamycin Complex 1), we identify several proteins implicated in yeast filamentous growth that directly associate with the TORC1 and investigate their roles in nitrogen starvation-dependent or independent differentiation in yeast. METHODOLOGY: We isolated the endogenous TORC1 by purifying tagged, endogenous Kog1p, and identified associated proteins by mass spectrometry. We established invasive and pseudohyphal growth conditions in two S. cerevisiae genetic backgrounds (Σ1278b and CEN.PK). Using wild type and mutant strains from these genetic backgrounds, we investigated the roles of TORC1 and associated proteins in nitrogen starvation-dependent diploid pseudohyphal growth as well as nitrogen starvation-independent haploid invasive growth. CONCLUSIONS: We show that several proteins identified as associated with the TORC1 are important for nitrogen starvation-dependent diploid pseudohyphal growth. In contrast, invasive growth due to other nutritional stresses was generally not affected in mutant strains of these TORC1-associated proteins. Our studies suggest a role for TORC1 in yeast differentiation upon nitrogen starvation. Our studies also suggest the CEN.PK strain background of S. cerevisiae may be particularly useful for investigations of nitrogen starvation-induced diploid pseudohyphal growth.

Effect of caloric restriction on life span of the housefly, Musca domestica.

Caloric restriction (CR) has been found to extend the life spans of a wide variety of species, transcending phylogenetic boundaries. The objective of this study was to test the generality of this phenomenon, using the male housefly as an insect model in which food intake can be quantified precisely. Sucrose was found to promote a longer life span than diets additionally containing proteins and lipids. Flies were fed sucrose or a more complex diet ad libitum (AL), or in amounts ranging from 50% to 100% of the average amount consumed by young flies. CR shortened rather than prolonged the life span of houseflies, particularly flies fed sucrose only. The rate of oxygen consumption was not affected by caloric restriction or by the exclusion of proteins and lipids from the diet, and the reproductive activity of male flies remained unchanged by sucrose feeding. Thus, it is unlikely that the life-shortening effects of CR can be explained either in terms of an adaptive response in metabolic rate or use of a suboptimal food source. Results of this study contradict the widely held view that CR has a life-extending effect in all species.

The changes of hepatic metallothionein synthesis and the hepatic damage induced by starvation in mice.

Metallothionein (MT) is induced in the liver not only by heavy metals, but also by stress such as starvation. However, the meaning of the induced MT during starvation has never been clear. In this study, we investigated the relationship between changes in hepatic MT synthesis and the hepatic damage that occurs during starvation. MT synthesis was assessed by measuring MT contents and the expression of the MT gene in the liver. The hepatic damage was assessed by measuring glutamic pyruvic transaminase (GPT) and glutamic oxaloacetic transaminase (GOT) activities in the serum. MT synthesis in the liver increased over the normal level by starvation, but decreased under the normal level by refeeding after starvation. Both GPT and GOT activities of the refeeding group were higher than those of the control group. However, MT synthesis increased by a subcutaneous injection with CdCl(2) (1 mg Cd /kg) at the same time as refeeding after starvation. At this point, GOT activity decreased until it reached the normal level. MT synthesis decreased by refeeding after starvation, and from the results found in this study, we proposed the hypothesis that the liver damage caused by refeeding after starvation might be due to the decrease in the synthesis of a sufficient amount of MT induced by metals.

Native fluorescence and excitation spectroscopic changes in Bacillus subtilis and Staphylococcus aureus bacteria subjected to conditions of starvation.

Fluorescence emission and excitation spectra were measured over a 7-day period for Bacillus subtilis (Bs), a spore-forming, and Staphylococcus aureus (Sa), a nonspore-forming bacteria subjected to conditions of starvation. Initially, the Bs fluorescence was predominantly due to the amino acid tryptophan. Later, a fluorescence band with an emission peak at 410 nm and excitation peak at 345 m, from dipicolinic acid, appeared. Dipicolinic acid is produced during spore formation and serves as a spectral signature for detection of spores. The intensity of the 410-nm band continued to increase over the next 3 days. The Sa fluorescence was predominantly from tryptophan and did not change over time. In 6 of the 17 Bs specimens studied, an additional band appeared with a weak emission peak at 460 cm and excitation peaks at 250, 270, and 400 nm. The addition of beta-hydroxybutyric acid to the Bs or the Sa cultures resulted in a two-order of magnitude increase in the 460-nm emission. The addition of Fe2+ quenched the 460 emission, indicating that a source of the 460-nm emission was a siderophore produced by the bacteria. We demonstrate that optical spectroscopy-based instrumentation can detect bacterial spores in real time.

Depletion of brain serotonin does not alter 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-induced starvation syndrome in the rat.

We have previously reported a series of biological events in 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-intoxicated rats which resulted in elevated brain serotonin (5-HT) levels, offering a possible explanation of the acute toxicity (reduced feed intake and death) in these animals. It was thus hypothesized that depletion of central 5-HT stores should alter the TCDD-induced starvation syndrome. Brain 5-HT was selectively depleted by intracerebroventricular infusions of the neurotoxin 5,7-dihydroxytrytamine (5,7-DHT). Subsequently the animals were given a lethal dose of TCDD. In rats treated with 5,7-DHT hypothalamic 5-HT was depleted up to 90% compared to control animals, yet TCDD induced the expected reduction of bodyweight and feed intake. These results suggest that although TCDD increases central 5-HT levels as a result of increased plasma tryptophan, this may not be the main cause for reduced feed intake and lethality in these animals.

T-2 toxin-enhanced resistance against listeriosis in mice: importance of gastrointestinal lesions.

The role of T-2 toxin-induced gastrointestinal lesions in T-2 toxin-enhanced resistance to listeriosis in mice was evaluated. The T-2 toxin-induced lesions did not cause a starvation effect sufficient to enhance resistance to listeriosis. Administration of polymyxin E markedly reduced the gram-negative intestinal microflora and did not eliminate the toxin-induced resistance to listeriosis. The T-2 toxin did not cause an increased expression of Ia surface antigens on peritoneal macrophages. Thus, toxin-induced anorexia and starvation or absorption of gram-negative intestinal bacteria and endotoxins through toxin-induced gastrointestinal lesions did not account for the enhancing effect of T-2 toxin on resistance to Listeria monocytogenes infection in mice.