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Browsing by Author "Childress, Paul J."
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Item A Translational Regulatory Mechanism Mediated by Hypusinated Eukaryotic Initiation Factor 5A Facilitates β-Cell Identity and Function(American Diabetes Association, 2024) Connors, Craig T.; Villaca, Catharina B. P.; Anderson-Baucum, Emily K.; Rosario, Spencer R.; Rutan, Caleb D.; Childress, Paul J.; Padgett, Leah R.; Robertson, Morgan A.; Mastracci, Teresa L.; Biology, School of ScienceAs professional secretory cells, β-cells require adaptable mRNA translation to facilitate a rapid synthesis of proteins, including insulin, in response to changing metabolic cues. Specialized mRNA translation programs are essential drivers of cellular development and differentiation. However, in the pancreatic β-cell, the majority of factors identified to promote growth and development function primarily at the level of transcription. Therefore, despite its importance, the regulatory role of mRNA translation in the formation and maintenance of functional β-cells is not well defined. In this study, we have identified a translational regulatory mechanism mediated by the specialized mRNA translation factor eukaryotic initiation factor 5A (eIF5A), which facilitates the maintenance of β-cell identity and function. The mRNA translation function of eIF5A is only active when it is posttranslationally modified ("hypusinated") by the enzyme deoxyhypusine synthase (DHPS). We have discovered that the absence of β-cell DHPS in mice reduces the synthesis of proteins critical to β-cell identity and function at the stage of β-cell maturation, leading to a rapid and reproducible onset of diabetes. Therefore, our work has revealed a gatekeeper of specialized mRNA translation that permits the β-cell, a metabolically responsive secretory cell, to maintain the integrity of protein synthesis necessary during times of induced or increased demand.Item Alterations to maternal cortical and trabecular bone in multiparous middle-aged mice(Hylonome, 2017-11) Gu, Alex; Sellamuthu, Rajendran; Himes, Evan; Childress, Paul J.; Pelus, Louis M.; Orschell, Christie M.; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineObjectives: During the reproductive cycle, altered calcium homeostasis is observed due to variable demand for mineral requirements. This results in increased bone resorption during the time period leading up to parturition and subsequent lactation. During lactation, women will lose 1-3% of bone mineral density per month, which is comparable to the loss experienced on an annual basis post-menopausal. The purpose of this study was to determine the effect of parity on bone formation in middle-aged mice. Methods: Mice were mated and grouped by number of parity and compared with age matched nulliparous controls. Measurements were taken of femoral trabecular and cortical bone. Calcium, protein and alkaline phosphatase levels were also measured. Results: An increase in trabecular bone mineral density was observed when comparing mice that had undergone parity once to the nulliparous control. An overall decrease in trabecular bone mineral density was observed as parity increased from 1 to 5 pregnancies. No alteration was seen in cortical bone formation. No difference was observed when calcium, protein and alkaline phosphatase levels were assessed. Conclusions: This study demonstrates that number of parity has an impact on trabecular bone formation in middle-aged mice, with substantial changes in bone density seen among the parous groups.Item Analysis of the effects of spaceflight and local administration of thrombopoietin to a femoral defect injury on distal skeletal sites(Springer Nature, 2021-03-26) Zamarioli, Ariane; Campbell, Zachery R.; Maupin, Kevin A.; Childress, Paul J.; Ximenez, Joao P.B.; Adam, Gremah; Chakraborty, Nabarun; Gautam, Aarti; Hammamieh, Rasha; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineWith increased human presence in space, bone loss and fractures will occur. Thrombopoietin (TPO) is a recently patented bone healing agent. Here, we investigated the systemic effects of TPO on mice subjected to spaceflight and sustaining a bone fracture. Forty, 9-week-old, male, C57BL/6 J were divided into 4 groups: (1) Saline+Earth; (2) TPO + Earth; (3) Saline+Flight; and (4) TPO + Flight (n = 10/group). Saline- and TPO-treated mice underwent a femoral defect surgery, and 20 mice were housed in space ("Flight") and 20 mice on Earth for approximately 4 weeks. With the exception of the calvarium and incisor, positive changes were observed in TPO-treated, spaceflight bones, suggesting TPO may improve osteogenesis in the absence of mechanical loading. Thus, TPO, may serve as a new bone healing agent, and may also improve some skeletal properties of astronauts, which might be extrapolated for patients on Earth with restraint mobilization and/or are incapable of bearing weight on their bones.Item Cohousing Male Mice with and without Segmental Bone Defects(American Association for Laboratory Animal Science, 2018-04) Rytlewski, Jeffrey D.; Childress, Paul J.; Scofield, David C.; Khan, Faisal; Alvarez, Marta B.; Tucker, Aamir T.; Harris, Jonathan S.; Peveler, Jessica L.; Hickman, Debra L.; Chu, Tien-Min G.; Kacena, Melissa A.; Biomedical Sciences and Comprehensive Care, School of DentistrySpaceflight results in bone loss like that associated with osteoporosis or decreased weight-bearing (for example, high-energy trauma such as explosive injuries and automobile accidents). Thus, the unique spaceflight laboratory on the International Space Station presents the opportunity to test bone healing agents during weightlessness. We are collaborating with NASA and the US Army to study bone healing in spaceflight. Given the unique constraints of spaceflight, study design optimization was required. Male mice were selected primarily because their femur is larger than females’, allowing for more reproducible surgical outcomes. However, concern was raised regarding male mouse aggression. In addition, the original spaceflight study design included cohousing nonoperated control mice with mice that had undergone surgery to create a segmental bone defect. This strategy prompted the concern that nonoperated mice would exhibit aggressive behavior toward vulnerable operated mice. We hypothesized that operated and nonoperated male mice could be cohoused successfully when they were cagemates since birth and underwent identical anesthetic, analgesic, preoperative, and postoperative conditions. Using quantitative behavioral scoring, body weight, and organ weight analyses (Student t test and ANOVA), we found that nonoperated and operated C57BL/6 male mice could successfully be housed together. The male mice did not exhibit aggressive behavior toward cagemates, whether operated or nonoperated, and the mice did not show evidence of stress, as indicated by veterinary assessment, or change in body or proportional organ weights. These findings allowed our mission to proceed (launched February 2017) and may inform future surgical study designs, potentially increasing housing flexibility.Item The Effects of High Fat Diet, Bone Healing, and BMP-2 Treatment on Endothelial Cell Growth and Function(Elsevier, 2021-05) Bhatti, Fazal Ur Rehman; Dadwal, Ushashi C.; Valuch, Conner R.; Tewari, Nikhil P.; Awosanya, Olatundun D.; Staut, Caio de Andrade; Sun, Seungyup; Mendenhall, Stephen K.; Perugini, Anthony J., III; Nagaraj, Rohit U.; Battini, Hanisha L.; Nazzal, Murad K.; Blosser, Rachel J.; Maupin, Kevin A.; Childress, Paul J.; Li, Jiliang; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineAngiogenesis is a vital process during the regeneration of bone tissue. The aim of this study was to investigate angiogenesis at the fracture site as well as at distal locations from obesity-induced type 2 diabetic mice that were treated with bone morphogenetic protein-2 (BMP-2, local administration at the time of surgery) to heal a femoral critical sized defect (CSD) or saline as a control. Mice were fed a high fat diet (HFD) to induce a type 2 diabetic-like phenotype while low fat diet (LFD) animals served as controls. Endothelial cells (ECs) were isolated from the lungs (LECs) and bone marrow (BMECs) 3 weeks post-surgery, and the fractured femurs were also examined. Our studies demonstrate that local administration of BMP-2 at the fracture site in a CSD model results in complete bone healing within 3 weeks for all HFD mice and 66.7% of LFD mice, whereas those treated with saline remain unhealed. At the fracture site, vessel parameters and adipocyte numbers were significantly increased in BMP-2 treated femurs, irrespective of diet. At distal sites, LEC and BMEC proliferation was not altered by diet or BMP-2 treatment. HFD increased the tube formation ability of both LECs and BMECs. Interestingly, BMP-2 treatment at the time of surgery reduced tube formation in LECs and humeri BMECs. However, migration of BMECs from HFD mice treated with BMP-2 was increased compared to BMECs from HFD mice treated with saline. BMP-2 treatment significantly increased the expression of CD31, FLT-1, and ANGPT2 in LECs and BMECs in LFD mice, but reduced the expression of these same genes in HFD mice. To date, this is the first study that depicts the systemic influence of fracture surgery and local BMP-2 treatment on the proliferation and angiogenic potential of ECs derived from the bone marrow and lungs.Item The effects of spaceflight and fracture healing on distant skeletal sites(Springer Nature, 2019-08-06) Dadwal, Ushashi C.; Maupin, Kevin A.; Zamarioli, Ariane; Tucker, Aamir; Harris, Jonathan S.; Fischer, James P.; Rytlewski, Jeffery D.; Scofield, David C.; Wininger, Austin E.; Bhatti, Fazal Ur Rehman; Alvarez, Marta; Childress, Paul J.; Chakraborty, Nabarun; Gautam, Aarti; Hammamieh, Rasha; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineSpaceflight results in reduced mechanical loading of the skeleton, which leads to dramatic bone loss. Low bone mass is associated with increased fracture risk, and this combination may compromise future, long-term, spaceflight missions. Here, we examined the systemic effects of spaceflight and fracture surgery/healing on several non-injured bones within the axial and appendicular skeleton. Forty C57BL/6, male mice were randomized into the following groups: (1) Sham surgery mice housed on the earth (Ground + Sham); (2) Femoral segmental bone defect surgery mice housed on the earth (Ground + Surgery); (3) Sham surgery mice housed in spaceflight (Flight + Sham); and (4) Femoral segmental bone defect surgery mice housed in spaceflight (Flight + Surgery). Mice were 9 weeks old at the time of launch and were euthanized approximately 4 weeks after launch. Micro-computed tomography (μCT) was used to evaluate standard bone parameters in the tibia, humerus, sternebra, vertebrae, ribs, calvarium, mandible, and incisor. One intriguing finding was that both spaceflight and surgery resulted in virtually identical losses in tibial trabecular bone volume fraction, BV/TV (24-28% reduction). Another important finding was that surgery markedly changed tibial cortical bone geometry. Understanding how spaceflight, surgery, and their combination impact non-injured bones will improve treatment strategies for astronauts and terrestrial humans alike.Item A fast-degrading thiol–acrylate based hydrogel for cranial regeneration(IOP, 2017-04) Emmakah, Arbi M.; Arman, Hussain E.; Bragg, John Campbell; Greene, T.; Alvarez, Marta B.; Childress, Paul J.; Goebel, William S.; Kacena, Melissa A.; Lin, Chien-Chi; Chu, Tien-Min Gabriel; Biomedical Sciences and Comprehensive Care, School of DentistrySuccessful regeneration of the cranium in patients suffering from cranial bone defects is an integral step to restore craniofacial function. However, restoration of craniofacial structure has been challenging due to its complex geometry, limited donor site availability, and poor graft integration. To address these problems, we investigated the use of a thiol–acrylate hydrogel as a cell carrier to facilitate cranial regeneration. Thiol–acrylate hydrogels were formulated with 5–15 wt% poly(ethylene glycol)-diacrylate (PEGDA) and 1–9 mm dithiothreitol (DTT). The degradation rate, swelling ratio, and shear modulus of the resulting hydrogel were first characterized. Then, pre-osteoblast-like cells (MC3T3-E1) were encapsulated in the hydrogel and cultured for up to 21 d. Our results demonstrate that compared to samples formulated from 15 wt% PEGDA, 5 wt% PEGDA samples showed lower storage modulus at day 10 (0.7 kPa versus 8.3 kPa), 62.7% higher in weight change after soaking for 10 d. While the 5 wt% PEGDA group showed an 85% weight loss between day 10 and 21, the 15 wt% PEGDA group showed a 5% weight gain in the same time period. Cell viability with 15 wt% PEGDA and 5 mm DTT hydrogel decreased by 41.3% compared to 5 wt% PEGDA and 5mM DTT gel at day 7. However, histological analysis of cells after 21 d in culture revealed that they had pericellular mineral deposition indicating that the cells were differentiating into osteoblasts lineage in all experimental groups. This study shows that thiol–acrylate hydrogels can be tailored to achieve different degradation rates, in order to enhance cell viability and differentiation. Thus, the findings of this study provide a fundamental understanding for the application of thiol–acrylate hydrogels in cranial bone regeneration.Item Gene-metabolite networks associated with impediment of bone fracture repair in spaceflight(Elsevier, 2021-06-08) Chakraborty, Nabarun; Zamarioli, Ariane; Gautam, Aarti; Campbell, Ross; Mendenhall, Stephen K.; Childress, Paul J.; Dimitrov, George; Sowe, Bintu; Tucker, Aamir; Zhao, Liming; Hammamieh, Rasha; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineAdverse effects of spaceflight on musculoskeletal health increase the risk of bone injury and impairment of fracture healing. Its yet elusive molecular comprehension warrants immediate attention, since space travel is becoming more frequent. Here we examined the effects of spaceflight on bone fracture healing using a 2 mm femoral segmental bone defect (SBD) model. Forty, 9-week-old, male C57BL/6J mice were randomized into 4 groups: 1) Sham surgery on Ground (G-Sham); 2) Sham surgery housed in Spaceflight (FLT-Sham); 3) SBD surgery on Ground (G-Surgery); and 4) SBD surgery housed in Spaceflight (FLT-Surgery). Surgery procedures occurred 4 days prior to launch; post-launch, the spaceflight mice were house in the rodent habitats on the International Space Station (ISS) for approximately 4 weeks before euthanasia. Mice remaining on the Earth were subjected to identical housing and experimental conditions. The right femur from half of the spaceflight and ground groups was investigated by micro-computed tomography (µCT). In the remaining mice, the callus regions from surgery groups and corresponding femoral segments in sham mice were probed by global transcriptomic and metabolomic assays. µCT confirmed escalated bone loss in FLT-Sham compared to G-Sham mice. Comparing to their respective on-ground counterparts, the morbidity gene-network signal was inhibited in sham spaceflight mice but activated in the spaceflight callus. µCT analyses of spaceflight callus revealed increased trabecular spacing and decreased trabecular connectivity. Activated apoptotic signals in spaceflight callus were synchronized with inhibited cell migration signals that potentially hindered the wound site to recruit growth factors. A major pro-apoptotic and anti-migration gene network, namely the RANK-NFκB axis, emerged as the central node in spaceflight callus. Concluding, spaceflight suppressed a unique biomolecular mechanism in callus tissue to facilitate a failed regeneration, which merits a customized intervention strategy.Item Loss of Nmp4 optimizes osteogenic metabolism and secretion to enhance bone quality(APS, 2019) Shao, Yu; Wichern, Emily; Childress, Paul J.; Adaway, Michele; Misra, Jagannath; Klunk, Angela; Burr, David B.; Wek, Ronald C.; Mosley, Amber L.; Liu, Yunlong; Robling, Alexander G.; Brustovetsky, Nickolay; Hamilton, James; Jacobs, Kylie; Vashishth, Deepak; Stayrook, Keith R.; Allen, Matthew R.; Wallace, Joseph M.; Bidwell, Joseph P.; Anatomy and Cell Biology, IU School of MedicineA goal of osteoporosis therapy is to restore lost bone with structurally sound tissue. Mice lacking the transcription factor Nuclear Matrix Protein 4 (Nmp4, Zfp384, Ciz, ZNF384) respond to several classes of osteoporosis drugs with enhanced bone formation compared to wild type (WT) animals. Nmp4-/- mesenchymal stem/progenitor cells (MSPCs) exhibit an accelerated and enhanced mineralization during osteoblast differentiation. To address the mechanisms underlying this hyper-anabolic phenotype, we carried out RNA-sequencing and molecular and cellular analyses of WT and Nmp4-/- MSPCs during osteogenesis to define pathways and mechanisms associated with elevated matrix production. We determined that Nmp4 has a broad impact on the transcriptome during osteogenic differentiation, contributing to the expression of over 5,000 genes. Phenotypic anchoring of transcriptional data was performed for the hypothesis-testing arm through analysis of cell metabolism, protein synthesis and secretion, and bone material properties. Mechanistic studies confirmed that Nmp4-/- MSPCs exhibited an enhanced capacity for glycolytic conversion- a key step in bone anabolism. Nmp4-/- cells showed elevated collagen translation and secretion. Expression of matrix genes that contribute to bone material-level mechanical properties were elevated in Nmp4-/- cells, an observation that was supported by biomechanical testing of bone samples from Nmp4-/- and WT mice. We conclude that loss of Nmp4 increases the magnitude of glycolysis upon the metabolic switch, which fuels the conversion of the osteoblast into a super-secretor of matrix resulting in more bone with improvements in intrinsic quality.Item Megakaryocyte and Osteoblast Interactions Modulate Bone Mass and Hematopoiesis(Mary Ann Liebert, 2018-05-15) Alvarez, Marta B.; Xu, LinLin; Childress, Paul J.; Maupin, Kevin A.; Mohamad, Safa F.; Chitteti, Brahmananda R.; Himes, Evan; Olivos, David J.; Cheng, Ying-Hua; Conway, Simon J.; Srour, Edward F.; Kacena, Melissa A.; Orthopaedic Surgery, School of MedicineEmerging evidence demonstrates that megakaryocytes (MK) play key roles in regulating skeletal homeostasis and hematopoiesis. To test if the loss of MK negatively impacts osteoblastogenesis and hematopoiesis, we generated conditional knockout mice where Mpl, the receptor for the main MK growth factor, thrombopoietin, was deleted specifically in MK (Mplf/f;PF4cre). Unexpectedly, at 12 weeks of age, these mice exhibited a 10-fold increase in platelets, a significant expansion of hematopoietic/mesenchymal precursors, and a remarkable 20-fold increase in femoral midshaft bone volume. We then investigated whether MK support hematopoietic stem cell (HSC) function through the interaction of MK with osteoblasts (OB). LSK cells (Lin-Sca1+CD117+, enriched HSC population) were co-cultured with OB+MK for 1 week (1wk OB+MK+LSK) or OB alone (1wk OB+LSK). A significant increase in colony-forming units was observed with cells from 1wk OB+MK cultures. Competitive repopulation studies demonstrated significantly higher engraftment in mice transplanted with cells from 1wk OB+MK+LSK cultures compared to 1wk OB+LSK or LSK cultured alone for 1 week. Furthermore, single-cell expression analysis of OB cultured±MK revealed adiponectin as the most significantly upregulated MK-induced gene, which is required for optimal long-term hematopoietic reconstitution. Understanding the interactions between MK, OB, and HSC can inform the development of novel treatments to enhance both HSC recovery following myelosuppressive injuries, as well as bone loss diseases, such as osteoporosis.