Abstract LB135: Deferiprone alters macrophage function and metabolism

We studied the effects of the intracellular, clinically approved, iron chelator deferiprone (DFP) on macrophage characteristics, function, and metabolism. This research expands on our previous studies investigating the ability of DFP to alter metabolism of breast and prostate cancer tumors and enhance treatment response. We used the murine macrophage cell line RAW 264.7, unpolarized (M0) & polarized (to M1 by LPS, to M2 by IL-4), in vitro to evaluate the effects of DFP on macrophage (i) doubling times (cell count assay), (ii) polarization (flow cytometry), (iii) functional response by measuring cytokine (IL-12, IL-10, TNFα), secretion (Luminex multiplex cytokine detection system, Millipore), phagocytosis (IgG-coated latex beads), and reactive oxygen species production (fluorometric detection), (iv) glycolytic and oxidative metabolism (Agilent xFe96 analyzer), and (v) glycolytic metabolism (measuring incorporation of 1-13C-glucose by 1H & 13C magnetic resonance spectroscopy (MRS) of cell extracts and supernatants). The EC50s of 48 h DFP exposure are 79±5 µM, 93±3 µM, and 114±5 µM for M0, M1, and M2-polarized RAW 264.7 cells, respectively. The effect of DFP is cytostatic and increases cell doubling times. Exposure to 100 µM DFP for 48 h increases the number of M1-polarized cells in M0 and M1 cultures, but not in M2-polarized cells. While M2-polarized cells secreted more anti-inflammatory IL-10 and less pro-inflammatory TNFα than M0 cells, their cytokine secretion was unaffected by DFP. M1-polarized cells stimulated the secretion of TNFα and IL-10. The IL-10 secretion may be a feedback mechanism to curtail the pro-inflammatory effects of LPS. DFP decreased IL-10 secretion by ~33% in M1-polarized cells, enhancing their M1 activation state. IL-12 secretion was minimal and inconsistent. The ~21% phagocytosis in M0 cells remained unchanged by M2 polarization and increased to ~37% in M1-polarized cells. DFP exposure increased phagocytosis efficiency in M0, M1, and M2-polarized cells but highest in M1 cells. While no detectable H2O2 was produced, RAW 264.7 cells make detectable nitric oxide (NO), with M1-polarized cells yielding the most NO. NO yield was unchanged by DFP. Like the results above, we found the greatest effect of DFP to be on mitochondrial metabolism in M1 macrophages, specifically, significant reductions of maximal, basal, and ATP-linked respiration. The increased suppression of oxidative metabolism in M1-polarized macrophages by DFP conforms with the observed reduction of anti-inflammatory cytokines. The DFP increased phagocytosis, specifically dominant in M1 macrophages, suggests an increased reliance on glycolysis. To support the above observations, we currently study the incorporation of 1-13C-Glucose into cellular metabolites of M0, M1, and M2-polarized cells without & with DFP. Our data support a pro-inflammatory effect of DFP on macrophages, which may enhance their anti-tumor effect in vivo through altering tumor and macrophage metabolism.

Citation Format: Ellen Ackerstaff, Sadna Budhu, Dov P. Winkleman, Soe S. Min, Jenny N. Ijoma, Inna S. Serganova, Ronald G. Blasberg, Taha Merghoub, Jason A. Koutcher. Deferiprone alters macrophage function and metabolism [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr LB135.

Maternal ethanol consumption before paternal fertilization: Stimulation of hypocretin neurogenesis and ethanol intake in zebrafish offspring

There are numerous clinical and pre-clinical studies showing that exposure of the embryo to ethanol markedly affects neuronal development and stimulates alcohol drinking and related behaviors. In rodents and zebrafish, our studies show that embryonic exposure to low-dose ethanol, in addition to increasing voluntary ethanol intake during adolescence, increases the density of hypothalamic hypocretin (hcrt) neurons, a neuropeptide known to regulate reward-related behaviors. The question addressed here in zebrafish is whether maternal ethanol intake before conception also affects neuronal and behavioral development, phenomena suggested by clinical reports but seldom investigated. To determine if preconception maternal ethanol consumption also affects these hcrt neurons and behavior in the offspring, we first standardized a method of measuring voluntary ethanol consumption in AB strain adult and larval zebrafish given gelatin meals containing 10% or 0.1% ethanol, respectively. We found the number of bites of gelatin to be an accurate measure of intake in adults and a strong predictor of blood ethanol levels, and also to be a reliable indicator of intake in larval zebrafish. We then used this feeding paradigm and live imaging to examine the effects of preconception maternal intake of 10% ethanol-gelatin compared to plain-gelatin for 14 days on neuronal development in the offspring. Whereas ethanol consumption by adult female HuC:GFP transgenic zebrafish had no impact on the number of differentiated HuC⁺ neurons at 28 h post-fertilization (hpf), preconception ethanol consumption by adult female hcrt:EGFP zebrafish significantly increased the number of hcrt neurons in the offspring, an effect observed at 28 hpf and confirmed at 6 and 12 days post-fertilization (dpf). This increase in hcrt neurons was primarily present on the left side of the brain, indicating asymmetry in ethanol's actions, and it was accompanied by behavioral changes in the offspring, including a significant increase in novelty-induced locomotor activity but not thigmotaxis measured at 6 dpf and also in voluntary consumption of 0.1% ethanol-gelatin at 12 dpf. Notably, these measures of ethanol intake and locomotor activity stimulated by preconception ethanol were strongly, positively correlated with the number of hcrt neurons. These findings demonstrate that preconception maternal ethanol consumption affects the brain and behavior of the offspring, producing effects similar to those caused by embryonic ethanol exposure, and they provide further evidence that the ethanol-induced increase in hcrt neurogenesis contributes to the behavioral disturbances caused by ethanol.

Embryonic Ethanol Exposure Affects the Early Development, Migration, and Location of Hypocretin/Orexin Neurons in Zebrafish

BACKGROUND

Embryonic ethanol (EtOH) exposure is known to increase alcohol drinking later in life and have long-term effects on neurochemical systems in the brain. With zebrafish having marked advantages for elucidating neural mechanisms underlying brain disorders, we recently tested and showed in these fish, similar to rodents, that low-dose embryonic EtOH stimulates voluntary consumption of EtOH while increasing expression of hypocretin/orexin (hcrt) neurons, a neuropeptide that promotes consummatory and reward-related behaviors. The goal of the present study was to characterize how embryonic EtOH affects early development of the hcrt system and produces persistent changes at older ages that may contribute to this increase in EtOH consumption.

METHODS

We utilized live imaging and Imaris software to investigate how low-dose embryonic EtOH (0.5%), administered from 22 to 24 hours postfertilization, affects specific properties of hcrt neurons in hcrt:EGFP transgenic zebrafish at different ages.

RESULTS

Time-lapse imaging from 24 to 28 hpf showed that embryonic EtOH increased the number of hcrt neurons, reduced the speed, straightness, and displacement of their migratory paths, and altered their direction early in development. At older ages up to 6 dpf, the embryonic EtOH-induced increase in hcrt neurons was persistent, and the neurons became more widely dispersed. These effects of embryonic EtOH were found to be asymmetric, occurring predominantly on the left side of the brain, and at 6 dpf, they resulted in marked changes in the anatomical location of the hcrt neurons, with some detected outside their normal position in the anterior hypothalamus again primarily on the left side.

CONCLUSIONS

Our findings demonstrate that low-dose embryonic EtOH has diverse, persistent, and asymmetric effects on the early development of hypothalamic hcrt neurons, which lead to abnormalities in their ultimate location that may contribute to behavioral disturbances, including an increase in EtOH consumption.

Skeletal response to treatment with teriparatide (TPD) after bisphosphonate in post-menopausal women with osteoporosis and a high prevalence of secondary risk factors in real-life setting of a metabolic bone clinic; effect of age and vitamin D status

PURPOSE

Teriparatide (TPD) is a skeletal anabolic agent used in patients with severe post-menopausal osteoporosis (PMO) and steroid-induced osteoporosis who are at hish risk of fracture. Predictors of therapeutic response to teriparatide in real-life setting are not well characterised. We investigated potential factors associated with teriparatide response in post-menopausal women with established osteoporosis.

METHODS

We carried out a retrospective survey of 48 women, aged 73.2 [7.5] years with severe osteoporosis and prevalent fractures treated with TPD according to the NICE criteria. BMD was measured at baseline, 6-12 and 18-24 months at the lumbar spine (LS), total hip (TH) and femoral neck (FN). Bone turnover markers, serum 25 (OH)vitamin D were determined at 3-12 and 12-24 months.

RESULTS

BMD increased at 6-12 months (% change mean [SEM] 6.5 [1.1] p = 0.004) and 18-24 months (8.45 % [1.2] p<0.001) at the LS. A significant increase in BMD was observed at FN (3.1 [1.3] % p = 0.02). Changes in BMD at the TH was higher in patients younger than 73 years compared to older women (% change in BMD 4.13 [1.64] % v/s -1.7 [1.1] p = 0.007). Baseline 25 (OH) vitamin D correlated with change in P1NP at 3-12 months (r = 0.45 p = 0.049).

CONCLUSIONS

TPD-induced changes in BMD at the TH appears may be dependent on age. Vitamin D status may influence the early anabolic effect to TPD. Our data suggest that these factors may be important considerations when initiating and optimising treatment with TPD, although further larger studies are needed to confirm these findings.

Bryostatin-1 promotes long-term potentiation via activation of PKCα and PKCε in the hippocampus

Activation of protein kinase C (PKC) by bryostatin-1 affects various functions of the central nervous system. We explored whether bryostatin-1 influenced synaptic plasticity via a process involving PKC. Our purpose was to examine whether bryostatin-1 affected the induction of hippocampal long-term potentiation (LTP) in Schaffer-collateral fibers (CA1 fibers) of the hippocampus, and/or influenced the intracellular Ca(2+) level of hippocampal neurons. We also determined the PKC isoforms involved in these processes. We found that bryostatin-1 strongly facilitated LTP induction, in a dose-dependent manner, upon single-theta burst stimulation (TBS). Further, intracellular Ca(2+) levels also increased with increasing concentration of bryostatin-1. The facilitative effects of bryostatin-1 in terms of LTP induction and enhancement of intracellular Ca(2+) levels were blocked by specific inhibitors of PKCα and PKCε, but not of PKCδ. Our results suggest that bryostatin-1 is involved in neuronal functioning and facilitates induction of LTP via activation of PKCα and/or PKCε.

Synthesis of new artemisinin analogues from artemisinic acid modified at C-3 and C-13 and their antimalarial activity

Artemisinic acid (2) was modified through allylic oxidation at C-3 or conjugate addition at C-13 to afford 12 methyl artemisinate derivatives (4-15). Photooxidation of the derivatives yielded eight new artemisinin analogues, including 13-cyanoartemisinin (16), 13-methoxycarbonyl artemisinin (17), 13-methoxyartemisinin (18), 13-ethylsulfonylartemisinin (19), 13-nitromethylartemisinin (20), 13-(1-nitroethyl)artemisinin (21), (3R)-3-hydroxyartemisinin (22), and (3R)-3-acetoxyartemisinin (23). Among the analogues, only compound 20 had antimalarial activity comparable to artemisinin (1).

A novel method for convenient assessment of arthritic pain in voluntarily walking rats

Quantification of arthritic pain can be very useful in elucidating the mechanisms of arthritis and in assessing the effect of anti-arthritic medication or treatment. Here we report a novel method that allows convenient measurements of the severity of arthritic pain in voluntarily walking rats. We constructed a device to measure the weight load on each leg while the animal was walking through a path, the bottom of which was equipped with strain gauge weight sensors. Using this device, we measured the weight load on the right hind leg before and after induction of arthritis by carrageenan injection into the knee joint cavity of this leg. The carrageenan injection resulted in a significant reduction of weight load on the affected leg; the load decreased to the minimum level at 4 h after the injection and gradually returned to the pre-injection level by the fifth day. Intraperitoneal administration of morphine at 5.5 h after carrageenan injection could reverse the weight load change. These results suggest that our new device is an effective tool for convenient measurements of arthritic pain in dynamic conditions like walking.

Improvements in dating tooth enamel by ESR

ESR dating requires that growth curves be determined by interpreting complex spectra. Spectra, however, can vary significantly in shape and field position between different samples, or occasionally between subsamples, even though the mineralogy remains the same. In some cases, this spectral variability does not affect the resulting accumulated dose calculation. In other cases, signal subtraction may be needed. However, some samples that until recently might have been considered unsuitable for dating are now shown to yield accurate and precise results because a broad interference peak is integral to the hydroxyapatite signal. By studying the spectrum at the Q-band frequency, it can be shown that the interfering signal in most cases is not a problem for dating. A second concern has been that artificially irradiating sample aliquots can introduce a short-lived component that is simply an unstable enhancement of the dating signal. The apparent accumulated dose from growth curves created immediately after irradiation is considerably greater than that after annealing, although the curve's shape remains unchanged. Annealing both the natural and artificially irradiated signal shows the dating signal's lifetime to be greater than 10(10) years.

Induction of cytotoxic T lymphocytes with peptides in vitro: identification of candidate T-cell epitopes in hepatitis B virus X antigen

Cytotoxic T lymphocytes (CTL) have been suggested to contribute to viral clearance during hepatitis B virus (HBV) infection. To induce effective CTL against viral infection by peptide vaccination, it is essential to identify the epitope peptides recognized by CTL. Here, 15 peptide sequences that contain HLA-A2.1-restricted CTL binding consensus motif were identified on hepatitis B virus X (HBx) protein and synthesized for further characterization. In the binding assay, 8 of 15 synthetic peptides enhanced the expression of HLA-A2.1 molecules on the surface of T2 cells, a human transport-associated antigen processing-deficient cell line. This result implies that these eight peptides are able to bind to the HLA-A2.1 molecules. These peptides were further tested for their ability to activate CTL from peripheral blood mononuclear cells (PBMCs) isolated from HBV chronic carriers. Five of eight tested peptides activated PBMC-derived T cells, resulting in the lysis of the target T2 cells pulsed with the same peptide. Furthermore, the CTL responses to HBx antigen in HBV chronic carriers were shown to be polyclonal, multispecific, and mediated mainly by CD8+ T cells. In contrast, these responses were not detected in uninfected healthy blood donors. Although the five CTL epitope peptides identified in this study have not been proven to be the naturally processed epitopes in HBV-infected hepatocytes, they could be candidates for peptide-based immunotherapy against HBV infection.

Synthetic peptides of human papillomavirus type 18 E6 harboring HLA-A2.1 motif can induce peptide-specific cytotoxic T-cells from peripheral blood mononuclear cells of healthy donors

To identify cytotoxic T-cell (CTL) epitopes against human papillomavirus type 18 (HPV 18) E6 protein that might be useful for developing peptide-based vaccine against HPV 18 infection, 18 peptides which possibly contain CTL epitopes were selected on the basis of previously described human leukocyte antigen (HLA)-A2.1-binding motif and chemically synthesized. In the binding assay of the synthetic peptides, 8 out of 18 synthetic peptides enhanced the expression of HLA-A2.1 molecules on T2 cell surface, which implies that these peptides were able to bind the HLA molecules. Those peptides having good binding affinity to HLA-A2.1 were tested for their ability to activate CTLs which were isolated from peripheral blood mononuclear cells (PBMCs) of healthy blood donors and to kill the target T2 cells pulsed with the same peptide. Five out of eight tested peptides activated CTLs and killed the target cells.