Corticotropin releasing hormone can selectively stimulate glucose uptake in corticotropinoma via glucose transporter 1

BACKGROUND
Pre-operative detection of corticotropin (ACTH) secreting microadenomas causing Cushing's disease (CD) improves surgical outcomes. Current best magnetic resonance imaging fails to detect up to 40% of these microadenomas. 18F-fluorodeoxyglucose (18F-FDG) positron emission tomography (PET) is specific, but not sensitive in detecting corticotropinomas. Theoretically, secretagogue stimulation with corticotropin releasing hormone (CRH) could improve detection of adenomas with 18F-FDG PET. Previous attempts with simultaneous CRH stimulation have failed to demonstrate increased 18F-FDG uptake in corticotropinomas. We hypothesized that CRH stimulation leads to a delayed elevation in glucose uptake in corticotropinomas.


METHODS
Clinical data was analyzed for efficacy of CRH in improving 18FDG-PET detection of corticotropinomas in CD. Glucose transporter 1 (GLUT1) immunoreactivity was performed on surgical specimens. Ex-vivo, viable cells from these tumors were tested for secretagogue effects (colorimetric glucose uptake), and for fate of intracellular glucose (glycolysis stress analysis). Validation of ex-vivo findings was performed with AtT-20 cells.


RESULTS
CRH increased glucose uptake in human-derived corticotroph tumor cells and AtT-20, but not in normal murine or human corticotrophs (p < 0.0001). Continuous and intermittent (1 h) CRH exposure increased glucose uptake in AtT-20 with maximal effect at 4 h (p = 0.001). Similarly, CRH and 8-Br-cAMP led to robust GLUT1 upregulation and increased membrane translocation at 2 h, while fasentin suppressed baseline (p < 0.0001) and CRH-mediated glucose uptake. Expectedly, intra-operatively collected corticotropinomas demonstrated GLUT1 overexpression. Lastly, human derived corticotroph tumor cells demonstrated increased glycolysis and low glucose oxidation.


CONCLUSION
Increased and delayed CRH-mediated glucose uptake differentially occurs in adenomatous corticotrophs. Delayed secretagogue-stimulated 18F-FDG PET could improve microadenoma detection.

Corticotropin releasing hormone (CRH) has secretagogue effects on adrenocorticotropic hormone or corticotropin (ACTH) secreting pituitary adenomas (Takano et al., 1996), but not on suppressed adjacent normal gland. This effect could theoretically improve the imaging detection of adenomas with 18 F-FDG PET imaging following secretagogue stimulation. However, our group (unpublished data) and others (Patt et al., 2014), have failed to demonstrate increased 18 F-FDG uptake in corticotropinomas by simultaneous CRH administration. To date, it remains unclear whether corticotropinomas are resistant to CRH-mediated glucose uptake, or if the effects are delayed.
We hypothesized that CRH stimulation leads to a delayed elevation in glucose uptake in corticotropinomas. In this study, we investigated the kinetics of CRH-modulated glucose uptake. A timecourse in-vitro study revealed that maximum glucose uptake occurs approximately 4 h post CRH administration. Moreover, we demonstrate for the first time that CRH stimulation results in a differential glucose uptake in adenomatous, but not in normal corticotrophs. Mechanistically, this was associated with a robust increase in glucose transporter 1 (GLUT1) expression. Taken together, these novel findings support the potential use of delayed 18 F-FDG PET imaging following CRH stimulation to improve microadenoma detection in CD.

Tissue sample collection
A total of 10 patients with CD were enrolled in a clinical trial (NIH 12-N-0067, NCT01459237) conducted at the National Institute of Neurological Diseases and Stroke (NINDS) to evaluate the utility of CRH-stimulated 18 F-FDG PET. Study was approved by the Combined Neuroscience Institutional Review Board (IRB). Pituitary adenoma tissues were obtained from these patients at the time of transsphenoidal adenomectomy at the National Institutes of Health Clinical Center (NIHCC) under a clinical trial (NIH 03-N-0164, NCT00060541) for subsequent immunohistochemical and metabolic analyses. Written informed consent was obtained from each patient for research study participation. The study was conducted in accordance to the standards and guidelines established by the IRB.

CRH-stimulated 18 F-FDG PET study
PET imaging was performed using a high-resolution research tomography scanner (Siemens AG). Each subject underwent two randomly ordered 18 F-FDG high resolution PET (hrPET) studies with and without CRH stimulation separated by at least 24 h. For CRH stimulated studies, ovine CRH (oCRH or Acthrel ® ) 1 mcg/kg (up to a maximum dose of 100 mcg) was administered immediately preceding 18 F-FDG administration (10 mCi). Pituitary metabolic activity was quantified using the standardized uptake values (SUV). Maximum SUV (SUV-Max) and averaged SUV (SUV-Avg) were calculated as previously described (Chittiboina et al., 2014).

Cell culture
AtT-20/D16:16 (a generous gift from Dr. Steven L. Sabol at the National Heart Lung and Blood Institute) murine corticotroph tumor cell lines were cultured in DMEM (Thermo Fisher Scientific, USA), 10% FCS (Thermo Fisher Scientific) following comparison with commercially available AtT-20 cells ( Supplementary Fig. 1). Cells were incubated for 2 h prior to all experiments in serum-free DMEM supplemented with 0.25% BSA (hereafter DMEM-BSA) and 90 mg/dL glucose, to simulate physiologic glucose levels. Pooled corticotroph cells were harvested (<30 min post-euthanasia) from female, BALB/c mice (aged 6e8 weeks; Taconic Biosciences, USA), digested and homogenized in 1 mg/mL collagenase (Sigma-Aldrich, USA) for 30 min, and cultured as above. All animals were euthanized in accordance with the standards and guidelines of the Institutional Animal Care and Use Committee of the National Institutes of Health (NIH). Western blot analysis was performed with anti glucocortidoid receptor antibody (Santa Cruz Biotechnology), anti Serine 211 phophorylated glucocorticoid receptor antibody (antibodies-online.com), and anti CRH receptor 1 antibody (Thermo Fisher Scientific).

Fluorescence activating sorting of murine corticotrophs
After dissociation of murine hypophyseal cells, corticotrophs were isolated by flow cytometry. Briefly, pooled cells were incubated with anti-CRH receptor 1 antibody (CRH-R1) (Thermo Fisher Scientific) for 1 h, followed by Alexa Fluor-555 conjugated antibody (Invitrogen, USA) and finally stained with DAPI (Thermo Fisher Scientific) for 30 min. Cell sorting analysis was carried out using MoFlo Astrios Cell Sorter and Summit Acquisition and Analysis software (Beckman Coulter, USA).

ACTH release studies
Following several washes in PBS, cells were incubated in serumfree DMEM-BSA and stimulated with 50 nM CRH (Sigma-Aldrich, USA), 100 nM arginine vasopressin (Sigma-Aldrich), 5 mM 8bromoadenosine 3 0 ,5 0 -cyclic monophosphate (8-Br-cAMP; Sigma-Aldrich), and/or 10 nM dexamethasone (DEX; Sigma-Aldrich) for the time points indicated. Media was then diluted and assessed via enzyme linked immunosorbant assay (MD Bioproducts, USA) according to manufacturer instructions. Glucose uptake experiments were conducted with Screen Quest Colorimetric Glucose Uptake Assay Kit (AAT Bioquest, USA) per manufacturer instructions. In brief, cells were cultured in DMEM-BSA on 96-well plates, washed with Krebs-Ringer-Phosphate-HEPES (KRPH) buffer and incubated in 90 ml/well of Glucose Uptake Buffer (AAT Bioquest) for 1 h. Subsequently, cells were exposed to 10 ml/well of Deoxy-D-glucose (2DOG) for 40min; cells in the CRH stimulation arm were exposed to 50 nM of CRH for 1 h. Following treatment, cells were washed with KRPH buffer and lysed. Lastly, 50 ml of the Uptake Assay Mixure (AAT Bioquest) was added to each sample and absorbance ratio was read with 570 nm wavelength.

RNA extraction and quantitative real-time PCR
Total RNA was extracted from cells using RNeasy Mini Kit (Qiagen, Germany) and reverse transcribed to complementary DNA (cDNA) with Superscript III qRT-PCR Supermix (Life Technologies, USA). Quantitative RT-PCR was performed using target-specific primers (Sigma-Aldrich; Supplementary Table 1) and SYBR Select Master Mix (Life Technologies) on an Illumina Eco Real-Time PCR System (Illumina, USA). Each reaction was performed in triplicate (technical and biological), and relative gene expression values were calculated using the DDCt method with ACTB as an internal control.

Immunofluorescence and immunohistochemistry
After CRH stimulation for various time periods, cells were fixed using 4% paraformaldehyde (Thermo Fisher Scientific) and blocked using 2% donkey serum in 2% PBSA. Tris-buffered saline with Tween was used as wash buffer. Cells were then incubated with primary antibody against GLUT1 (Abcam, UK) for 1 h and secondary donkey anti-rabbit FITC antibody (Jackson ImmunoResearch, USA) along with DAPI (Thermo Fisher Scientific) was applied to the cells for 30 min. Rabbit IgG was used as negative control. Plasma membrane translocation of GLUT1 was calculated as previously described (Cai et al., 2013). Briefly, ImageJ software (ImageJ 1.50i, NIH, Bethesda) was used to measure the relative fluorescence intensity of GLUT1 in the plasma membrane adjacent region and the cytosolic region. The ratio of these measurements was calculated in at least 8 cells per condition tested. Formalin fixed human derived surgical adenoma specimens were stained with GLUT1 antibody (Abcam, UK) using Leica BondMax (Leica Biosystems, Buffalo Grove, IL) and reviewed by blinded neuropathologist (ARC).

Statistical analysis
Statistical analyses were determined by one-factor ANOVA using GraphPad Prism version 6.0 software program (GraphPad, USA) for in-vitro and in-vivo results. Grouped analyses were evaluated using two-way ANOVA. Alpha level threshold of 0.05 was used to assess statistical significance.
Murine pituitary cells also expressed GR, phosphorylated GR similar to AtT20 cells. However, CRHR1 expression was lower in unsorted normal murine pituitary cells, with non-significant change upon dexamethasone exposure ( Supplementary Fig. 3). As expected, levels of measured ACTH were substantially lower in isolated normal murine corticotrophs (following fluorescence activating sorting), when compared to AtT-20 cells (Fig. 1A). When stimulated with CRH, a significant increase in ACTH secretion was observed in AtT-20 cells after 4 h (mean difference 84.7%, [95% CI 64.5e104.9], ANOVA p < 0.0001) (Fig. 1A). AtT-20 cells exposed to CRH displayed a significant increase in 2DOG uptake, while the same effect was not observed in normal murine corticotrophs (Fig. 1B). We then tested the effect of continuous CRH stimulation (at 1 and 4 h) on human-derived pituitary corticotroph tumor cells. At 1 and 4 h following initiation of CRH stimulation, a consistent increase in 2DOG uptake (mean difference 216 ± 38% and 222 ± 59%, respectively) was observed (Fig. 1C). We then confirmed the selectivity of secretagogue effect on glucose uptake in normal pituitary and corticotropinoma tissues ex-vivo from one patient. Expectedly, CRH stimulation led to a significant increase in ACTH secretion from human derived corticotroph tumor cells but not normal corticotrophs cells in primary culture (mean difference 225.6% [95% CI 21.1e430.2], ANOVA p ¼ 0.04) (Fig. 1D). Furthermore, 2DOG uptake was differentially increased in human derived corticotroph tumor cells but not in normal corticotrophs when exposed to CRH (mean difference 76.3%, [95% CI 50.5e102.2], ANOVA p < 0.0001) (Fig. 1E). These results suggest that adenomatous cells but not normal corticotrophs have increased glucose uptake that may be modulated with secretagogues stimulation.
Intracellular effects of CRH stimulation are largely mediated by the ubiquitous second messenger cyclic adenosine monophosphate (cAMP) (Gigu ere et al., 1982), therefore, we hypothesized that glucose uptake would increase in response to cAMP. Continuous exposure to 8-Br-cAMP revealed a slightly different pattern of delayed increase in 2DOG uptake as significant glucose uptake was seen at the 1, 2, 4 and 8-h mark ( (Fig. 2D). Taken together, these results suggest that secretagogues stimulation may lead to a delayed (2e4 h) increase in glucose uptake in adenomatous corticotrophs. Fig. 1. CRH stimulation results in selective augmented glucose uptake in adenomatous but not normal corticotrophs. Normal murine corticotrophs cells were separated from harvested pituitary glands using CRH-R1 antibody and flow cytometry. As expected, murine derived AtT-20/D16:16 cells demonstrated a robust CRH-stimulated ACTH secretion response not seen in normal murine corticotrophs (A). At 4 h, a significant increase in normalized 2DOG uptake was noted in AtT-20 cells exposed to CRH but not in normal murine corticotrophs (B). At 1 and 4 h, CRH stimulation resulted in a consistent increase in 2DOG uptake in human derived corticotroph tumor cells (C). Horizontal line at 100 represents 2DOG uptake by adenomatous cells at baseline. The individual data points represent 2DOG uptake normalized to adenoma without stimulation (y axis ¼ 100) at 1 and 4 h. When human derived corticotroph tumor cells were exposed to CRH for 4 h, a substantial increase in both ACTH release and glucose uptake was seen (D and E). Normal corticotrophs did not respond to CRH stimulation for both ACTH secretion or 2DOG uptake demonstrating the selective CRH-mediated effect on adenomatous cells only. *p 0.05, ****p 0.0001 compared with corresponding control values. Horizontal bars represent mean ± standard deviation. Abbreviations: ACTH -adrenocorticotropic hormone, CRH -corticotropinreleasing hormone, hCt e normal corticotrophs, hCtT e human derived corticotroph cells, mCt e normal murine corticotrophs. Fig. 2. Continuous and short-term exposure to CRH or 8-Br-cAMP leads to increased glucose uptake in AtT-20/D16:16 cells. Panels A and B represent normalized 2DOG uptake by AtT-20 cells. When exposed to CRH continuously (A), no increase in 2DOG was seen at early time points (1 and 2 h). 2DOG uptake was significantly elevated at 4 h with further delay up to 24 h. With a short-term 1 h (Tr-CRH) exposure to CRH (B), increased 2DOG was seen at 2 h followed by later time points. Exposure to 8-Br-cAMP resulted in delayed increases in 2DOG uptake with both continuous (Cont-cAMP) and transient (Tr-cAMP) exposure (C and D). The increase in CRH-mediated 2DOG uptake in AtT-20 cells was reduced in the presence of DEX (E). Despite a 3 h exposure to DEX, CRH stimulation still resulted in a significant increase in 2DOG uptake when compared to the control group (E). In AtT20 cells, AVP failed to induce significant increase in 2DOG uptake, with or without DEX (E). The data presented is representative of experiments carried out with biological duplicates and technical quadruplicates. *p 0.05, **p 0.01, ***p 0.001, ****p 0.0001 compared with corresponding control values. The horizontal line at 100 represents 2DOG uptake under control conditions. Horizontal bars represent mean ± standard deviation. Abbreviations: 2DOG -2deoxyglucose, 8-Br-cAMP -8Br-cyclic adenosine monophosphate, CRH -corticotropin-releasing hormone, DEX e dexamethasone, Cont-CRH e continuous corticotropin-releasing hormone, Cont cAMP e continuous cyclic adenosine monophosphate Tr-CRH e transient corticotropin-releasing hormone, Tr-cAMP e transient cyclic adenosine monophosphate.
Next, we wanted to understand the contribution of cAMP mediated effects of CRH receptor activation on glucose uptake. When AtT-20 cells were stimulated with continuous 8-Br-cAMP, GLUT1 exhibited significant transcriptional upregulation at 1 h, 4 h, 8 h and 24 h ( Supplementary Fig. 2). Expression of the remaining glucose transporters decreased when exposed to 8-Br-cAMP ( Supplementary Fig. 2). These findings also suggest transcriptional regulation of GLUT1 with secretagogue stimulation via cAMP production.

CRH augments GLUT1 expression and translocation to the membrane
Next, we confirmed the effect of secretagogue stimulation on GLUT1 expression and translocation in AtT-20/D16:16 cells. We exposed cells to both CRH and 8-Br-cAMP continuously for 2 h, 8 h and 24 h. Immunofluorescence revealed upregulation of GLUT1 within cells in response to stimulation (Fig. 4). This effect was seen as early as 2 h when compared to control (Fig. 4A-a, b and c). Relative fluorescence ratio of GLUT1 signal between plasma membrane adjacent region versus cytosolic region was increased from 0.9 to 1.16 within 2 h (p < 0.05). At 24 h of continuous CRH exposure, the ratio increased from 0.68 to 1.21 (p < 0.0001) (Fig. 4B). GLUT1 plasma membrane translocation was not increased in AtT20 cells exposed to 8-Br-cAMP (Fig. 4A-c, f and I, 4B), suggesting cAMP independent effect of CRH receptor activation.

Corticotropinomas have increased GLUT1 expression compared to suppressed normal gland
Clinically, concurrent CRH stimulation and 18 F-FDG PET failed to improve standardized uptake value of 18 F-FDG or adenoma detection in 10 patients (Table 1). A histopathological analysis was performed blindly on intra-operatively obtained human tissue by an experienced neuropathologist (A.R.) with both H&E stained, and GLUT1 immunostained sections available (Fig. 4C). Corticotroph adenomas in 9 out of 10 patients demonstrated immunoreactive cyptosolic GLUT1 expression (Table 1). In 3 patients where adjacent normal gland was available, the adjacent normal gland was negative for immunoreactive GLUT1 (Table 1). Increased immunoreactive cytosolic GLUT1 expression in corticotropinoma was not correlated with increased glucose uptake on FDG-PET scanning ( Table 1), suggesting that basal cytosolic GLUT1 expression was not related to increased glucose uptake per se.

Human-derived corticotroph tumor cells are highly dependent on glycolysis
Lastly, we investigated the fate of glucose within humanderived corticotroph tumor cells. Normally, the pituitary gland depends on free fatty acids as an energy source (Vannucci and Hawkins, 1983;Viña et al., 1984). Expectedly (Oldfield and Merrill, 2015), we found that corticotropinoma cells demonstrated higher glycolytic activity compared to normal gland (50.47% vs. 38.99%, Fig. 5A). However, the absolute level of glucose oxidation in corticotropinoma cells was quite low (Fig. 5B). In order to establish the dependency of corticotroph tumors cells on mitochondrial oxidative phosphorylation and/or anaerobic glycolysis, ETO, BPTES, and UK5099 were employed to block oxidation of fatty acids, glutamine, and glucose, respectively. Similarly, FCCP, an electron transport chain uncoupling agent was subsequently utilized to block oxidative phosphorylation pathways. Human-derived corticotroph tumor cells utilized up to 70e80% of their glycolytic capacity but less than 15% of their glucose oxidation capacity (Fig. 5) suggesting that these cells were highly dependent on anaerobic glycolysis.

Discussion
18 F-FDG PET reveals increased glucose uptake in both nonfunctioning and hormone secreting pituitary adenomas (De Souza et al., 1990;Bergstr€ om et al., 1987), whilst minimal 18 F-FDG uptake is usually seen in the normal gland (Ju et al., 2017;Hyun et al., 2011;Jeong et al., 2010). Sellar 18 F-FDG uptake is highly specific (Ju et al., 2017;Jeong et al., 2010;Koo et al., 2006), but a relatively insensitive (40%) finding for pituitary adenomas (Chittiboina et al., 2014;Alzahrani et al., 2009). Low sensitivity of 18 F-FDG-PET suggests the need for modulation of glucose uptake in adenomas to improve detection. In hormone secreting cells, secretagogues can further stimulate glucose uptake (Filetti et al., 1987;Harris et al., 2012), offering an ability to modulate glucose uptake in these cells. Consistent with other reports (Patt et al., 2014), our study failed to demonstrate an immediate change in standardized uptake value (SUV) with concomitant administration of CRH and 18 F-FDG in 10 human subjects (Table 1). These findings led us to investigate whether corticotropinomas are resistant to CRH-mediated glucose uptake, or if the effects are delayed. We hypothesized that CRH stimulation leads to delayed increased glucose uptake in corticotropinomas. Glucose kinetic studies demonstrated an increase in Fig. 3. CRH stimulation results in transcriptional upregulation of GLUT1. Expression of glucose transporters was calculated by DDCt method following RT-qPCR. GLUT1 is overexpressed throughout the period of continuous exposure to CRH in AtT20 D16:16 cells starting at 2 h (A). Other glucose transporters are variably expressed during CRH exposure. The response to CRH was modest at early time points for GLUT2 (B) and GLUT 3 (C) whilst GLUT3 seemed to have a delayed response at 24 h (C). No significant increase was noted for GLUT4 (D). GLUT8 reflected a similar pattern of expression when compared to GLUT1 with a less robust increase (E). The duration of exposure is denoted within each panel with an arrow underneath 'CRH'. CRH-mediated glucose uptake in AtT-20 cells was blunted by GLUT1 inhibitor Fasentin following a 3-h exposure (F). However, CRH exposure reversed the decreased glucose uptake caused by a lower dose of Fasentin (1 mM). A higher dose of fasentin (40 mM) dose prevented CRH mediated normalization of glucose uptake.
This reduction below baseline likely due to the large effect of high dose Fasentin on of glucose uptake at baseline (F). The data shown is representative of experiments carried out in both biological and technical triplicates. *p 0.05, **p 0.01, ***p 0.001, ****p 0.0001 compared with corresponding control values. Horizontal bars represent mean ± standard errors of mean (SEM). Abbreviations: CRH -corticotropin-releasing hormone, GLUT e glucose transporter, PCR -polymerase chain reaction. glucose uptake in ACTH-secreting AtT-20/D16:16 cells but not in normal murine corticotrophs cells in response to CRH stimulation. Further, selective modulation of glucose uptake with CRH was confirmed in human-derived corticotropinoma when compared to adjacent normal pituitary tissue. These findings are consistent with evidence suggesting that 18 F-FDG uptake is specific to residual/ recurrent pituitary adenoma following adenomectomy (Zhao et al., 2014).
A time-course study revealed that both continuous and transient administration of CRH leads to delayed increase glucose uptake in AtT-20 cells. CRH-mediated glucose uptake was maximal at 4 h for continuous CRH exposure, and 2e4 h for transient (1 h) CRH exposure. As intracellular effects of CRH stimulation are largely mediated by cAMP (Gigu ere et al., 1982), we deemed important to assess whether it was the main downstream mediator of CRH effects on glucose uptake. Continuous 8-Br-cAMP administration led to increased uptake at early time points from 1 to 4 h whereas transient exposure maximal effect was seen at 8 h. The difference in Fig. 4. GLUT1 is overexpressed in pituitary adenomas and its translocation increases with CRH administration. Fluorescence immunocytochemistry revealed increase in total GLUT1 content within AtT20/D16:16 cells with CRH and 8-Br-cAMP stimulation (A: b to i). This effect was seen as early as 2 h (A: b and c). Continuous CRH stimulation resulted in a robust and sustained GLUT1 membrane translocation (A: e and h). Representative immunofluorescence images are shown. GLUT1 membrane tranlocation was quantified as relative fluorescence ratio between averaged plasma membrane region versus cytosolic region using eight representative cells for each condition (B). The middle bars demonstrate a significant increase in GLUT1 localization to plama membrane region with 2-h (p < 0.05) and 24-h (p < 0.0001) exposure to CRH. Pituitary adenomas (asterix) harvested from patients who underwent transsphenoidal adenomectomy had higher GLUT1 expression than the surrounding pituitary gland (black arrowhead) (C). Adjacent histopathological sections of surgical specimens were examined with hematoxylin and eosin staining (top) and with GLUT1 immunohistochemical staining (bottom). Corticotropinoma demonstrated increased GLUT1 expression not associated with normal anterior pituitary gland (bottom, black arrowhead). Scale bars for fluorescence immunocytochemistry ¼ 10 mm. Scale bars for immunohistochemistry ¼ 100 mm. Abbreviations: DAPI -4 0 ,6-diamidino-2-phenylindole, GLUT1 e glucose transporter 1. time-dependent stimulation effect between CRH and 8-Br-cAMP might be due to the broad actions of CRH on AtT-20 cells not solely relying on the well-characterized cAMP transduction pathway. Interestingly, previous literature showed that little net oxidation of glucose by either the Krebs' cycle or the pentose phosphate pathway occurs in the pituitary gland in-vivo and that nonesterified fatty acids are one of the main energy substrates (Vannucci and Hawkins, 1983;Viña et al., 1984). Our results suggest that pituitary adenomas undergo metabolic reprogramming to rely on glycolysis as the primary energy source, similar to the Warburg effect in malignant tumors (Vander Heiden et al., 2009). CD is characterized by a state of hypercortisolemia that could inhibit glucose uptake in adenomatous (or AtT-20) cells (Booth et al., 1998). Our results suggest that even in the presence of DEX, CRH stimulation may lead to significant delayed increase in glucose uptake in corticotropinomas. A number of glucose transporters are involved in glucose uptake by cells of the central nervous system (Maher et al., 1994). We identified GLUT1 overexpression in 10 human corticotropinomas and identified GLUT1 as the predominant glucose transporter modulated by CRH stimulation. Both CRH and 8-Br-cAMP led to a robust increase in GLUT1 transcription maintained up to 24 h. This is consistent with previous studies in which gonadotrophin releasing hormone (GnRH) increased GLUT1 expression and stimulated glucose uptake in the gonadotrophs (Harris et al., 2012). Intriguingly, CRH stimulation resulted in a more robust and sustained membrane translocation of GLUT1 when compared to 8-Br-cAMP. We found a discordance between human corticotropinoma cytosolic GLUT1 expression and 18 F-FDG uptake (Table 1) presumably due to delayed glucose uptake effects. We thus suspect that in clinical use, exposure to oCRH may lead to delayed increased membrane translocation of GLUT1 within corticotropinomas, and consequently increase 18 F-FDG uptake. Additionally, we found that fasentin, a selective GLUT1 inhibitor, abolished the CRH-mediated increased glucose uptake, confirming the potential role of GLUT1 in glucose uptake in corticotropinomas. Given the dependence of adenomatous cells on glucose as a primary energy source, these results may lead to selective anti-tumor therapies by targeting glucose metabolism.

Conclusion
In this study, we demonstrate that CRH stimulation results in differentially increased glucose uptake from adenomatous but not in normal corticortrophs. A clinically relevant transient CRH exposure time-course study revealed that maximum uptake is 4 h post exposure. Corticotrophs do not normally utilize glucose at baseline as an energy source, however, glucose kinetic analyses suggest that a potential metabolic switch to aerobic glycolysis occurs in adenomatous cells. Based on these findings, we suggest a pathophysiologic basis for delayed 18 F-FDG PET imaging following  (Tumor 1 and 2) utilized the majority of their glycolytic capacity but barely used glucose for oxidation (B). OCR and ECAR were detected using Seahorse in human primary cells Tumor 1 and Tumor 2. The first stages of C and D and the first stages of E and F were generated using the same data. X-axis was extended to mimic continuous treatments. Data between two dash lines in each part were average of the first and third stages. Note that UK5099 caused minimal changes of OCR while oxamate led to significant alterations of ECAR in both samples. Abbreviations: ECAR e extracellular acidification rate, OCR e oxygen consumption rate.
CRH stimulation for detection of corticotropinomas. We are now confirming these findings with a clinical trial to detect corticotropinomas with 18F-FDG PET imaging 2e6 h following oCRH stimulation.

Disclosure statement
The authors declare no potential conflicts of interest.

Financial support
This research was supported by the Intramural Research Program of the National Institute of Neurological Diseases and Stroke, Bethesda, MD (NIH ZIA NS003150-01).