Spaceflight is associated with several health issues including diminished immune efficiency. Effects of long-term spaceflight on selected immune parameters of wild type (Wt) and transgenic mice over-expressing pleiotrophin under the human bone-specific osteocalcin promoter (PTN-Tg) were examined using the novel Mouse Drawer System (MDS) aboard the International Space Station (ISS) over a 91 day period. Effects of this long duration flight on PTN-Tg and Wt mice were determined in comparison to ground controls and vivarium-housed PTN-Tg and Wt mice. Levels of interleukin-2 (IL-2) and transforming growth factor-beta1 (TGF-β1) were measured in mucosal and systemic tissues of Wt and PTN-Tg mice. Colonic contents were also analyzed to assess potential effects on the gut microbiota, although no firm conclusions could be made due to constraints imposed by the MDS payload and the time of sampling. Spaceflight-associated differences were observed in colonic tissue and systemic lymph node levels of IL-2 and TGF-β1 relative to ground controls. Total colonic TGF-β1 levels were lower in Wt and PTN-Tg flight mice in comparison to ground controls. The Wt flight mouse had lower levels of IL-2 and TGF-β1 compared to the Wt ground control in both the inguinal and brachial lymph nodes, however this pattern was not consistently observed in PTN-Tg mice. Vivarium-housed Wt controls had higher levels of active TGF-β1 and IL-2 in inguinal lymph nodes relative to PTN-Tg mice. The results of this study suggest compartmentalized effects of spaceflight and on immune parameters in mice.
Citation: McCarville JL, Clarke ST, Shastri P, Liu Y, Kalmokoff M, et al. (2013) Spaceflight Influences both Mucosal and Peripheral Cytokine Production in PTN-Tg and Wild Type Mice. PLoS ONE 8(7): e68961. doi:10.1371/journal.pone.0068961
Editor: Sudha Agarwal, Ohio State University, United States of America
Received: December 21, 2012; Accepted: June 3, 2013; Published: July 10, 2013
Copyright: © 2013 McCarville et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: The authors have no support or funding to report.
Competing interests: The authors have declared that no competing interests exist.
Multiple studies have demonstrated that spaceflight has both short and long term physiological effects, in human and animal subjects. These effects include bone loss, cardiovascular alteration (cardiac atrophy and change in heart rhythm), muscle loss, and immune dysfunction, among others . Specifically, it has been reported that spaceflight modifies the immune system by altering cytokine production  and lymphocyte numbers, specifically T cells . Although the effects of spaceflight on the immune system have been the focus of several studies, there is currently a lack of knowledge with respect to how the gut microbiota is altered in spaceflight and under microgravity conditions, and the consequent impact on the immune system. Therefore, colonic contents were analyzed to determine whether effects on the gut microbiota could also be detected. The gut microbiota is known to affect both mucosal and systemic immunity, including IgA-secreting plasma cells, CD4+ T cell populations and antimicrobial peptide secretion, as well as altering intestinal epithelial cell cytokine expression , , , . Therefore, changes in the gut microbiota during spaceflight and under microgravity conditions may also affect the immune system. Transgenic mice over-expressing pleiotrophin under the human bone specific osteocalcin promoter (PTN-Tg) and wild type (Wt) mice were also used for this study , allowing for additional insight into effects of this transgene on the immune system under both flown and ground control conditions. PTN is part of the midkine family of heparin-binding growth factors, and is involved in osteogenesis and bone formation, as well as neurogenesis, cell proliferation and inflammation , . Decreased bone density and bone mass are issues associated with space flight . The PTN-Tg mouse model was selected for the leading study in the MDS mission flown aboard the ISS, in order to determine whether PTN over-expression would provide protection from bone loss due to microgravity , . The aim of present study was to examine effects of long-term space flight on immune parameters and the gut microbiota, through participation in a tissue-sharing program . However, as little is currently known about the effects of PTN overexpression on immune parameters, the use of both wild type and PTN-Tg mice in the MDS system also provided a novel opportunity to examine effects of PTN overexpression and of long-duration space flight on the immune system.
While numerous effects of spaceflight on the immune system have been reported, the potential contribution of spaceflight-associated effects on the gut microbiota to such changes has received little attention to date. Increasing evidence points to numerous interactions of the gut microbiota with the immune system , and determining effects of spaceflight on the gut microbiota, and the subsequent outcomes for immune activity will be valuable for optimizing long-term space flight conditions. To gain insight into these interactions utilizing a limited quantity and range of tissues, our focus was on cytokines previously reported to be affected by spaceflight, important for immune regulatory or effector activity, and responsive to gut microbiota changes: TGF-β1 and IL-2 , .
TGF-β1 is a multifunctional cytokine that plays an integral role in adaptive immunity, mucosal immunoregulation as well as bone formation, osteoblast proliferation and differentiation, and is influenced by the gut microbiota , . TGF-β1 is often considered a regulatory cytokine, involved in intestinal immune homeostasis and control of T cell activity and differentiation . Previous studies have demonstrated that TGF-β1 is down-regulated in certain tissues under microgravity conditions, including reduced TGF-β1 mRNA levels in bone and in osteoblasts, as well as decreased osteoblast TGF-β1 production ,,,. While little is currently known about interactions between PTN-Tg and TGF-β1, concurrent upregulation of PTN and TGF-β1 has been reported in chlorhexidine gluconate (CG)-induced fibrosis . Given the role of TGF-β1 in osteoimmunology and the previously documented effects of microgravity on TGF-β1 expression, we also hypothesized that mice overexpressing pleiotrophin may have differential TGF-β1 production under both space flight and ground conditions. IL-2 is essential for T cell proliferation and differentiation of specific T-cell subsets, including the differentiation of naïve CD4+ T cells into T helper 1 cells and promotion of CD8+ T cell proliferation. However, it plays other roles, such as increasing antibody secretion from plasma cells . Previous studies have indicated IL-2 production decreased in astronauts following spaceflight. Specifically, lower levels of post-flight IL-2 production by CD4+ and CD8+ T cells have been observed . The same pattern has been shown in rats following spaceflight, where the percentage of splenic T cells (TCR+/CD4+) was reduced in comparison to ground controls . Quantification of the cytokines TGF-β1 and IL-2 in mice that have had prolonged exposure to spaceflight would thus provide insight into the consequences for T cell activity and differentiation in both PTN-Tg and Wt mice, as well potential effects on bone formation, which are two key issues for astronaut health during long-duration spaceflight.
In this component of the MDS Experiment on the ISS, we examined effects on selected mucosal and systemic immune parameters and also attempted to assess the effects on the gut microbiota by examining the colonic community in flight mice, in the corresponding ground and vivarium controls, and in transgenic versus Wt mice. The lack of gut community diversity made inferences into interactions of gut microbiota and the immune system difficult, as did the limited number of mice surviving the flight. However, due to the unique nature of the MDS experiment and inability to readily conduct additional replicates, we carried out analysis of the TGF-β1 and IL-2 levels in the available tissue and analysis of the colonic microbiota community, and provide here an observational analysis of the findings. These results may provide further insight not only into effects of spaceflight on the immune system in systemic and mucosal compartments, but also into design issues for future studies aiming to examine effects of long term space flight on the gut microbiota, and associated effects on host parameters.
Full details regarding the MDS Experiment and flight opportunity have been previously described in Cancedda et al., 2012 . Unfortunately, there was a limited sample number for this experimental analysis due to the poor survival rate of the space flight mice. Upon returning to earth, there were 2 surviving PTN-Tg mice and a single Wt mouse. The ground control sample numbers were adjusted to match those of the flight mice. Tavella et al., 2012 have previously outlined details concerning consequences and timing of rodent death for both flight mice and ground controls . The limited sample number was not ideal for comparing the effects of long-term space flight on cytokine levels between PTN-Tg and Wt groups, and statistical analysis was only possible for the comparing these two groups in the vivarium controls. The observations made throughout this portion of the MDS study do however contribute further to the overall investigation of effects of long term space flight made possible through a tissue-sharing program. The findings from this unique experimental situation may provide groundwork for future studies aboard the ISS, and illustrate certain design issues that will be important for studies examining effects of spaceflight on the gut microbiota and interactions with host parameters. All animals involved in the trial gained weight by experiment completion, as previously reported . Gross necropsy of the colonic and lymphoid tissues did not reveal any abnormal changes in the gastrointestinal structure or mucosal tissue.
Effects of Long Term Space Flight on Colonic TGF-β1 and IL-2 in Wt and PTN-Tg Mice
Both TGF-β1 (active and total) and IL-2 were quantified within the colonic tissue of PTN-Tg and Wt mice, in order to observe the effects of long-term space flight on cytokine production at the mucosal level (Table 1). PTN-Tg mice showed variable levels of colonic IL-2 in the ground control, vivarium and flight conditions compared to IL-2 levels in Wt colonic tissue, which were undetectable in all but one mouse. The highest levels of active and total TGF-β1 were also observed in the PTN-Tg ground controls, and one of the Vivarium-housed mice. PTN-Tg and Wt ground control mice were compared to their flight counterparts in order to elucidate the effect of spaceflight on this parameter of mucosal immunity. TGF-β1 (active and total) levels in PTN-Tg mice were lower under flown conditions, and were undetectable in the Wt flight mouse, in contrast to the much higher level of total TGF-β1 in the Wt ground control. Both colonic IL-2 and active TGF-β1 were below the level of quantification for the ground control Wt mouse and the flown WT mouse. Statistical analysis was only possible for comparison of the colonic TGF-β1 levels in Wt vivarium control and PTN-Tg vivarium control mice, and no significant difference was observed.
Effects of Long Term Space Flight on Inguinal Lymph Node Cytokine Levels of Wt Mice Relative to PTN-Tg Mice
Wt mice appeared to be affected by flight more so than their transgenic counterparts with respect to inguinal node cytokine production, but additional testing would be required to confirm this observation. As shown in Table 2, the lowest inguinal IL-2 levels were observed in the Wt flight mouse compared to the PTN-Tg flight mice. The Wt and transgenic ground control mice had similar IL-2 levels. Flight appears not to have had any discernable effects on inguinal node IL-2 levels in the transgenic mice. The flown PTN-Tg mice compared to the PTN-Tg ground control mice had similar inguinal IL-2 levels.
Levels of TGF-β1 in the inguinal lymph nodes of Wt mice compared to PTN-Tg mice were different under flight conditions. The percentage of active TGF-β1 was higher in the Wt flight mouse compared to the PTN-Tg flight mice (Table 3). The Wt and PTN-Tg ground control mice had similar percentages of active TGF-β1. Vivarium-housed PTN-Tg mice had significantly lower levels of active TGF-β1 (Figure 1) and IL-2 (Figure 2) compared to Wt mice. Though statistical comparisons were not possible against ground or flown mice, the pattern of active TGF-β1 and IL-2 in the inguinal nodes of the vivarium-housed mice appears reversed compared to flown mice, but similar to ground control mice.
TGF-β1 was quantified from homogenized inguinal tissue of Wt and PTN-Tg vivarium housed mice by ELISA. The PTN-Tg mice had lower amounts of active TGF-β1 compared to the Wt. * Indicates statistical significance (p = 0.05) by unpaired Welch corrected t test.
IL-2 was quantified from homogenized inguinal tissue of Wt and PTN-Tg vivarium housed mice by ELISA. The PTN-Tg mice had lower amounts of IL-2 compared to the Wt. * Indicates statistical significance (p = 0.05) by unpaired Welch corrected t test.
Production of TGF-β1 and IL-2 in Brachial Lymph Nodes of Wt and PTN-Tg under Spaceflight and Ground Control Conditions
The brachial lymph node homogenate was investigated for effects of the PTN-Tg mutation and of spaceflight on peripheral cytokine production by quantifying the levels of IL-2 in addition to total and active TGF-β1 (Table 4). IL-2 concentrations were lower in the brachial lymph nodes of both PTN-Tg and Wt mice under flight conditions when compared to the ground controls. The level of IL-2 in the brachial nodes of the Wt flight mouse was higher than that observed in either of the PTN-Tg flight mice, similar to the pattern seen in the brachial nodes of the ground control mice. However, there was no statistically significant difference observed in the brachial lymph node IL-2 concentrations of the Wt and PTN-Tg mice housed in vivarium conditions.
Total TGF-β1 levels were lower in brachial nodes of PTN-Tg mice than the Wt mouse in ground control conditions, but the lowest total brachial TGF-β1 levels were observed in vivarium-housed mice. The flown Wt mouse exhibited decreased levels of active and total TGF-β1 in flight conditions when compared to levels in the Wt ground control. Conversely, the brachial nodes of PTN-Tg mice had higher levels of both active and total TGF-β1 in the flight condition when compared to levels in ground controls. Notably, the brachial lymph node concentrations of active TGF-β1 of the PTN-Tg mice were higher in flown conditions than in the Wt counterpart, as was the percent active TGF-β1. Under flight conditions, the percent active TGF-β1 was lower in the Wt mouse and higher in the PTN-Tg mice compared to levels in ground controls, although statistical analysis was not possible due to the limited sample size.
Statistical analysis was only possible for mice housed under vivarium conditions; however the difference in TGF-β1 (active, total and percent active) in the brachial lymph nodes between PTN-Tg and Wt mice was not statistically significant.
Gut Microbiota and Spaceflight
Colonic contents collected from mice subjected to spaceflight, the corresponding MDS ground control, and from vivarium-housed mice were examined in order to determine whether spaceflight affected the gut community. All of these samples were liquid and contained no visible particulate material. Analysis of pyrosequencing data yielded a total of 137 phylotypes shared among these samples. Cluster analysis comparing the colonic community among each sample indicated little difference in the microbiota of mice exposed to spaceflight versus those in the corresponding ground control MDS system (Figure 3). In all cases, these communities were dominated by a single phylotype homologous with Lactobacillus reuteri, which encompassed 84–99% of the total phylotypes within each of these samples. Colonic samples from the vivarium-housed mice were richer and mostly clustered further away, but were also dominated by this phylotype, although to a lesser degree (10–60% of total phylotypes). A common feature was the uneven diversity within each sample.
The present study investigated the effects of long-duration spaceflight on selected immune system parameters in both Wt and PTN-Tg mice. While considerable evidence points to changes in the efficacy of the immune system during spaceflight , , it is currently not known whether these changes are to any extent due to flight-induced alterations in the gut microbiota. The MDS experiment provided a unique opportunity not only to determine effects of long-duration spaceflight on the immune system, and potentially on the gut microbiota, but also to examine these effects in the context of the PTN-Tg mutation.
TGF-β1 is a highly conserved, pleotropic cytokine with varied effects on numerous cell types, including regulation of B cell differentiation and class switching, attenuation and regulation of Natural Killer (NK) cell activity and regulation of dendritic cells (DC) maturation and antigen-presenting activity , , . Immunoregulatory activity of TGF-β1 also reflects its profound impact on T cell activity and differentiation , and TGF-β1 is integral in maintaining intestinal immune homeostasis , . For example, TGF-β1 is involved in conditioning mucosal DCs to a phenotype supporting differentiation of T Helper (TH) cells to the regulatory T cell (Treg) phenotype, which are in turn essential for maintaining intestinal immune homeostasis and controlling excessive inflammatory responses at the mucosal interface , . TGF-β1 is also a class switching factor for B cells, promoting production of IgA, the predominant mucosal antibody isotype .
In addition to its integral role in the immune system, TGF-β1 also plays a role in wound healing and fibrosis, and bone formation , . Bone loss is a well-documented issue associated with spaceflight, and decreased bone formation has been identified as a contributing factor , . TGF-β1 is involved in induction of bone formation, and TGF-β1 mediated signalling is involved in skeletal development . Compartment-specific reduction in skeletal TGF-β1 mRNA levels following spaceflight have been observed in rats , suggesting decreased osteoblast activity. Decreased post flight levels of TGF-β1 and TGF-β2 mRNA in cultured human fetal osteoblastic cells  and reduced TGF-β1 production by rat osteoblasts following 4 and 5 days of flight, relative to ground controls have also been reported . Microgravity-induced decreases in osteoblast TGF-β1 mRNA levels have been shown to return to normal under artificial onboard gravity conditions , further illustrating the effects of space flight on this cytokine.
In this component of the MDS study, the effect of spaceflight on mucosal immunity was examined by quantifying IL-2 and TGF-β1 levels within colonic tissue of flight and ground control mice, as well as in vivarium controls. Our results suggest a spaceflight associated decrease in total TGF-β1 levels in colonic tissue of PTN-Tg mice and the Wt mouse. Given the role of TGF-β1 in Treg induction and development , the decrease in total TGF-β1 could be associated with declining T cell numbers, as observed in other spaceflight studies . These observed changes in mucosal TGF-β1 production could be the consequence of external factors such as microgravity, although the potential effect of gut microbiota interactions with the mucosal immune system cannot be ruled out.
Activation of T cells requires extensive cell-cell communication and signal transduction, effected through appropriate ligand-receptor recognition. An important cytokine which activates resting T cells is IL-2, secreted by activated TH cells. In this study, it was observed that the Wt mouse under flight conditions produced lower IL-2 levels in systemic tissues (brachial and inguinal lymph nodes) compared to its ground control counterpart. Similar results with respect to IL-2 production were observed by Gridley et al. (2009) when splenocytes from flight mice were activated by anti-CD3 stimulation . They postulated that the lowered IL-2 production could be due to alterations in T cell signal transduction . A previous study attempted to reverse the negative effects of spaceflight on T cell populations in rats by administering pegylated interleukin-2 (PEG-IL-2), however, this treatment was unable to oppose the effects of spaceflight . This suggests that the effects of spaceflight on T cell populations are not solely due to decreased IL-2 production. Our study did not investigate T cell populations specifically, however, due to the integral role of IL-2 in T cell activation, diminished levels of IL-2 could reflect reduced T cell activation and proliferation in space-flight conditions.
The percentage of active TGF-β1 in the inguinal nodes was somewhat higher in the Wt flown mouse compared to the ground control, but an opposite pattern emerged in the brachial lymph nodes. Microgravity shifts the normal head-to-foot hydrostatic gradient, leading to fluid retention in the upper extremities and limiting pressure to the cervical areas . Changes in lymph recirculation under microgravity conditions could influence cellular migration, potentially resulting in alterations in cell populations within peripheral lymph nodes. If fluid shift effects of microgravity influence T cell populations in lymph nodes, they may also account for the decreased levels of IL-2 observed in both inguinal and brachial lymph nodes of the flight mice, as similar results have been observed for mice under simulated microgravity conditions .
Exposure to low gravity plays a role in the inhibition of lymphocyte proliferation due to its impact on cytokine secretion, T cell locomotion and differential structuring of lymphocyte cytoskeletal elements . Thus prolonged spaceflight may lead to suppressed immune responses. Though difficult to ascertain with certainty due to the small experimental sampling pool, it appears that immune suppression may have occurred in Wt mice during spaceflight based on the pattern of TGF-β1 and IL-2 production in systemic locations. This may be due to a multitude of reasons, including lower T cell proliferation due to selective changes in adhesion molecules expressed on lymphocytes during spaceflight . Other possibilities include thymic atrophy  leading to lower T cell populations or altered T cell populations due to changes induced by flight stress, radiation and low gravity , and differential cell trafficking between tissues due to microgravity induced fluid shift .
The PTN-Tg mice in this study were over-expressing pleiotrophin under control of the human bone-specific osteocalcin promoter . The impact of this transgene in spaceflight has never been investigated prior to this long term (91 day) flight using the MDS system on the ISS, where PTN-Tg expression exerted a protective effect against microgravity-induced bone loss through increased osteoblast activity , . Within the colon, a mucosal tissue, there was a decrease in TGF-β1 (active and total) and IL-2 in PTN-Tg flight mice relative to ground control mice. This same pattern was also observed with total TGF-β1 levels in the Wt flight mouse. Therefore, although the PTN-Tg mice expressed higher levels of TGF-β1 both on the ground and in flight, the transgene had little effect on preventing cytokine level decreases in flight. Interestingly, PTN-Tg flight mice showed no decrease in inguinal node IL-2 or TGF-β1 levels or in brachial node TGF-β1 levels, relative to PTN-Tg ground control mice, in contrast to the lower levels observed in these systemic tissues of the Wt flight mouse. This could potentially be due to the transgene increasing bone mass, and perhaps the efficiency of producing lymphocytes from bone marrow. Previously, it has been observed that microgravity negatively affects expansion and differentiation of stem cells into lymphocyte and monocytes . If this were the case, the effects of spaceflight on T cell populations in PTN-Tg mice could be lower than those in Wt mice.
The effect of over-expressing PTN under the osteocalcin promoter on immune parameters has received little attention to date. In this study, it was observed that the levels of IL-2 in both lymph node tissues of Wt and PTN-Tg were lower in vivarium conditions when compared to ground control counterparts. These differences in vivarium in relation to ground control conditions may be due to the nature of the housing environment, or to decreased stressors. Reduced production of TGF-β1 in PTN knockout mice in response to CG treatment has been previously reported . However, higher levels of active TGF-β1 were quantified in the inguinal lymph node tissues of vivarium-housed Wt mice, suggesting that PTN overexpression may decrease TGF-β1 production or activation, suggesting a complex relationship between these mediator molecules. It has been previously demonstrated that adult mice with PTN over-expression have long term impairment of bone healing and bone strength . Since TGF-β1 has strong influences in bone remodelling and structure , decreases in levels of this cytokine may lead to decreased bone strength. It would be interesting to determine whether the lower levels of active TGF-β1 observed in the vivarium PTN-Tg mice are directly caused by PTN over-expression.
The observation that the collected colonic contents contained no visible particulate material and that the communities consisted primarily of a single L. reuteri strain made it impossible to assess the potential impacts of spaceflight on the gut community in any of the mice. Gut transit time in mice is very fast, having been estimated at approximately 4.5 hours . One possible explanation is that the mice were in a “fasted” state at the arrival to the Space Life Science Laboratory at the Kennedy Space Center (KSC). This is deduced from the fact that the MDS payload was switched to the “survival” mode about three days before the landing at KSC , and mice tend to finish eating their ration shortly after 5 g of food is dispensed by the food delivery system . Even if the mice had consumed food between the arrival to SLSL and the time of dissection, the food digest could have been retained in the stomach or small intestine, resulting in the observed scant colonic content. Unfortunately neither stomach nor small intestine, nor their contents were made available to us. Our results illustrate the potential for design factors such as timing of feeding, to influence analysis of gut microbiota diversity. Design of future studies to analyze the impact of spaceflight on the gut microbiota will need to integrate strategies to deal with the challenges and constraints imposed by such elements as housing design, feed delivery and animal management during landing.
In summary, while spaceflight-associated differences were observed in colonic tissue and systemic lymph node levels of IL-2 and TGF-β1, direct correlations with effects on the gut microbiota could not be made, due to the scant colonic content. These immune alterations could result from a variety of factors including impeded movement of lymphatic fluids, effects of microgravity on T cell populations, or from spaceflight-associated effects on the gut microbiota.
Future studies could potentially address these elements, as well as investigate the site of cytokine production. It was not possible to perform histopathology or immunohistochemistry experiments in this study since the limited sample number and diminutive proportions only provided enough tissue for homogenate cytokine analysis. Such experiments could provide insight as to whether immunological adaptations to space flight took place in the lymphoid tissues. However, it must be noted that changes in immune parameters, and potentially even in the gut microbiota may not be due to microgravity itself, but instead due to other elements such as changes in diet, exposure to radiation or even psychological stressors and the resulting neuro-immune interactions . Further study would be valuable in order to determine the extent of the effects on cytokine production and the roles played by these factors relative to direct effects of microgravity in both Wt and PTN-Tg mice.
Materials and Methods
Animals and Animal Habitat
Details regarding the mouse drawer system and exposure of C57BL/10J Wt and PTN-Tg mice to zero gravity on the ISS have been previously described in “The Mice Drawer System Experiment and the Space Endurance Record-Breaking Mice” (2012) PLoS Collections , , , , . Mice were 8 weeks old at launch. Three Wt and three PTN-Tg mice were housed in the MDS system, and delivered via the Space Shuttle Discovery (Space Transport System (STS)-128 mission) to the ISS on August 28th, 2009. The surviving 1 Wt and 2 PTN-Tg mice were returned to earth after 91 days, via the Space Shuttle Atlantis (STS-129 mission). The authors participated in a tissue sharing process, receiving specific samples (brachial and inguinal lymph nodes, colon and colonic contents) at the end of the flight period. During the tissue collection, a Biospecimen Reporting for Improved Study Quality (BRISQ) checklist was employed to ensure specimen uniformity. Animal care protocols were approved by the University of Ontario Institute of Technology (UOIT) Animal Care Committee, the American Institutional Animal Care and Use Committee (IACUC), Ethics Committee of the Animal Facility of the National Institute for Cancer Research (Genova, Italy) and by the Public Veterinary Health Department of the Italian Ministry of Health.
Sample Preparation and Storage
The inguinal and brachial lymph nodes and colonic tissue were removed by dissection; flash frozen, shipped immediately to UOIT and stored at -80°C. To prepare the samples, tissues were weighed and suspended in phosphate buffered saline with 0.5% protease inhibitor cocktail and DMSO (P8340– Sigma, St. Louis, MO). Tissues were homogenized using a Tissuemiser homogenizer (Fisher Scientific, Hampton, NH) and centrifuged (16 100×g, 30 min). The supernatants were collected and the centrifugation process was repeated until tissue and fat were no longer prevalent in the supernatant. The final products were stored at -80°C for future assay.
Contents contained within the colon of each mouse (~100 mg/mouse) were recovered during dissection and frozen at −80°C. DNA was recovered from each sample by first grinding in liquid nitrogen then purified using the QIAamp DNA stool mini kit (Qiagen Inc, Mississauga, ON). Bacterial tag-encoded FLX amplicon pyrosequencing was performed as previously described  using the forward primer F44  and the reverse primer R519 . Initial sequence processing was carried out using Esprit . Phylotypes within each sample were screened to identify suspected chimeric sequences determined using Chimera-Slayer  as implemented through Mothur . Suspected chimeric sequences and phylotypes encompassing <2 reads per sample were removed. Phylotypes within each sample were trimmed to an equal length, aligned and clustered at a 0.03% sequence divergence using Mothur. Neighbour-joining trees were generated using seaview  with Jukes Cantor correction  and 1000 iterations. Additional sequences aligning within a <3% sequence divergence were further binned together. This was repeated until the core phylotypes within each sample set were identified. Shared phylotypes were identified by pooling the core phylotypes across all samples and processed as carried out for each sample. Phylotype classification was determined using the Seq-match program available through the ribosome data project .
TGF-β1 and IL-2 Cytokine Quantification
Both TGF-β1 and IL-2 were quantified by enzyme linked immunosorbent assay (ELISA), using kits DY240 and DY402 respectively, (R&D Systems, Minneapolis, MN) and high affinity protein binding ELISA plates (Greiner Bio-One). Microcentrifuge tubes were siliconized with Sigmacote® (SL2 - Sigma, St. Louis, MO) prior to preparation of dilutions and activation of samples for TGF-β1 quantification. Levels of both active and total TGF-β1 were determined. Activation of TGF-β1 samples to remove the Latency Associated Protein (LAP) was carried out using standard acidification protocols as outlined by R&D Systems. The optical density was determined using a Synergy HT plate reader (BioTEK, Winooski, VT) at 405 nm.
Statistical analyses were performed in InStat 3 (GraphPad Software, La Jolla, CA) using unpaired two-tailed T-tests. However, statistical analysis was not possible for all ground controls and space flight mice due to the small sample size which survived flight. For cluster analysis, phylotype frequency distributions were first calculated for each colonic sample with abundance normalized by expressing the contribution of each individual phylotype as a percent of the total sample. This data was pooled then subjected to cluster analysis using Statistica (Statsoft, Tulsa, OK) using city block distances .
We thank Nadia Trieselmann, Shauna Nolan and Matthew O’Hara for their contributions to this work.
Conceived and designed the experiments: STC JLM PS YL MK SPJB JMGJ. Performed the experiments: STC JLM PS YL MK. Analyzed the data: STC JLM PS MK SPJB JMGJ. Contributed reagents/materials/analysis tools: YL. Wrote the paper: STC JLM PS YL MK SPJB JMGJ.
- 1. White RJ, Averner M (2001) Humans in space. Nature 409: 1115–1118. doi: 10.1038/35059243
- 2. Crucian BE, Cubbage ML, Sams CF (2000) Altered cytokine production by specific human peripheral blood cell subsets immediately following space flight. J Interferon Cytokine Res 20: 547–556. doi: 10.1089/10799900050044741
- 3. Gridley DS, Slater JM, Luo-Owen X, Rizvi A, Chapes SK, et al. (2009) Spaceflight effects on T lymphocyte distribution, function and gene expression. J Appl Physiol 106: 194–202. doi: 10.1152/japplphysiol.91126.2008
- 4. Macpherson AJ, Uhr T (2004) Compartmentalization of the mucosal immune responses to commensal intestinal bacteria. Ann N Y Acad Sci 1029: 36–43. doi: 10.1196/annals.1309.005
- 5. Cash HL, Whitham CV, Behrendt CL, Hooper LV (2006) Symbiotic bacteria direct expression of an intestinal bactericidal lectin. Science 313: 1126–1130. doi: 10.1126/science.1127119
- 6. Sekirov I, Russell SL, Antunes LC, Finlay BB (2010) Gut microbiota in health and disease. Physiol Rev 90: 859–904. doi: 10.1152/physrev.00045.2009
- 7. Renz H, Brandtzaeg P, Hornef M (2012) The impact of perinatal immune development on mucosal homeostasis and chronic inflammation. Nat Rev Immunol 12: 9–23. doi: 10.1038/nri3112
- 8. Tavella S, Ruggiu A, Giuliani A, Brun F, Canciani B, et al. (2012) Bone turnover in wild type and pleiotrophin-transgenic mice housed for three months in the International Space Station (ISS). PLoS one 7: e33179. doi: 10.1371/journal.pone.0033179
- 9. Yokoi H, Kasahara M, Mori K, Ogawa Y, Kuwabara T, et al. (2012) Pleiotrophin triggers inflammation and increased peritoneal permeability leading to peritoneal fibrosis. Kidney Int 81: 160–169. doi: 10.1038/ki.2011.305
- 10. Tare RS, Oreffo RO, Clarke NM, Roach HI (2002) Pleiotrophin/Osteoblast-stimulating factor 1: dissecting its diverse functions in bone formation. J Bone Miner Res 17: 2009–2020. doi: 10.1359/jbmr.2002.17.11.2009
- 11. Cancedda R, Liu Y, Ruggiu A, Tavella S, Biticchi R, et al. (2012) The Mice Drawer System (MDS) Experiment and the Space Endurance Record-Breaking Mice. PLoS one 7: e32243. doi: 10.1371/journal.pone.0032243
- 12. Green-Johnson JM (2012) Immunological responses to gut bacteria. J AOAC Int 95: 35–49. doi: 10.5740/jaoacint.sge_green-johnson
- 13. Atarashi K, Tanoue T, Shima T, Imaoka A, Kuwahara T, et al. (2011) Induction of colonic regulatory T cells by indigenous Clostridium species. Science 331: 337–341. doi: 10.1126/science.1198469
- 14. Donkor ON, Ravikumar M, Proudfoot O, Day SL, Apostolopoulos V, et al. (2012) Cytokine profile and induction of T helper type 17 and regulatory T cells by human peripheral mononuclear cells after microbial exposure. Clin Exp Immunol 167: 282–295. doi: 10.1111/j.1365-2249.2011.04496.x
- 15. Li MO, Wan YY, Sanjabi S, Robertson AK, Flavell RA (2006) Transforming growth factor-beta regulation of immune responses. Annu Rev Immunol 24: 99–146. doi: 10.1146/annurev.immunol.24.021605.090737
- 16. Bonewald LF, Dallas SL (1994) Role of active and latent transforming growth factor beta in bone formation. J Cell Biochem 55: 350–357. doi: 10.1002/jcb.240550312
- 17. Hughes-Fulford M, Rodenacker K, Jutting U (2006) Reduction of anabolic signals and alteration of osteoblast nuclear morphology in microgravity. J Cell Biochem 99: 435–449. doi: 10.1002/jcb.20883
- 18. Kasagi S, Chen W (2013) TGF-beta1 on osteoimmunology and the bone component cells. Cell Biosci 3: 4. doi: 10.1186/2045-3701-3-4
- 19. Izcue A, Coombes JL, Powrie F (2009) Regulatory lymphocytes and intestinal inflammation. Annu Rev Immunol 27: 313–338. doi: 10.1146/annurev.immunol.021908.132657
- 20. Westerlind KC, Turner RT (1995) The skeletal effects of spaceflight in growing rats: tissue-specific alterations in mRNA levels for TGF-beta. J Bone Miner Res 10: 843–848. doi: 10.1002/jbmr.5650100603
- 21. Harris SA, Zhang M, Kidder LS, Evans GL, Spelsberg TC, et al. (2000) Effects of orbital spaceflight on human osteoblastic cell physiology and gene expression. Bone 26: 325–331. doi: 10.1016/s8756-3282(00)00234-9
- 22. Kumei Y, Morita S, Shimokawa H, Ohya K, Akiyama H, et al. (2003) Inhibition of HSP70 and a collagen-specific molecular chaperone (HSP47) expression in rat osteoblasts by microgravity. Ann N Y Acad Sci 1010: 476–480. doi: 10.1196/annals.1299.086
- 23. Liao W, Lin JX, Leonard WJ (2011) IL-2 family cytokines: new insights into the complex roles of IL-2 as a broad regulator of T helper cell differentiation. Curr Opin Immunol 23: 598–604. doi: 10.1016/j.coi.2011.08.003
- 24. Pecaut MJ, Simske SJ, Fleshner M (2000) Spaceflight induces changes in splenocyte subpopulations: effectiveness of ground-based models. Am J Physiol Regul Integr Comp Physiol 279: R2072–2078.
- 25. Laouar Y, Sutterwala FS, Gorelik L, Flavell RA (2005) Transforming growth factor-beta controls T helper type 1 cell development through regulation of natural killer cell interferon-gamma. Nat Immunol 6: 600–607. doi: 10.1038/ni1197
- 26. Geissmann F, Revy P, Regnault A, Lepelletier Y, Dy M, et al. (1999) TGF-beta 1 prevents the noncognate maturation of human dendritic Langerhans cells. J Immunol 162: 4567–4575.
- 27. Gorelik L, Flavell RA (2000) Abrogation of TGF-beta signaling in T cells leads to spontaneous T cell differentiation and autoimmune disease. Immunity 12: 171–181. doi: 10.1016/s1074-7613(00)80170-3
- 28. Coombes JL, Siddiqui KR, Arancibia-Carcamo CV, Hall J, Sun CM, et al. (2007) A functionally specialized population of mucosal CD103+ DCs induces Foxp3+ regulatory T cells via a TGF-beta and retinoic acid-dependent mechanism. J Exp Med 204: 1757–1764. doi: 10.1084/jem.20070590
- 29. Iliev ID, Spadoni I, Mileti E, Matteoli G, Sonzogni A, et al. (2009) Human intestinal epithelial cells promote the differentiation of tolerogenic dendritic cells. Gut 58: 1481–1489. doi: 10.1136/gut.2008.175166
- 30. Suzuki K, Ha SA, Tsuji M, Fagarasan S (2007) Intestinal IgA synthesis: a primitive form of adaptive immunity that regulates microbial communities in the gut. Semin Immunol 19: 127–135. doi: 10.1016/j.smim.2006.10.001
- 31. Sanford GL, Harris-Hooker S, Lui J, Bosah FN (1999) Wound healing following injury to vascular smooth muscle cell cultures is modulated by culture under hypergravity. J Gravit Physiol 6: P29–30.
- 32. Cann CE, Adachi RR (1983) Bone resorption and mineral excretion in rats during spaceflight. Am J Physiol 244: R327–331.
- 33. Morey ER, Baylink DJ (1978) Inhibition of bone formation during space flight. Science 201: 1138–1141. doi: 10.1126/science.150643
- 34. Datta HK, Ng WF, Walker JA, Tuck SP, Varanasi SS (2008) The cell biology of bone metabolism. J Clin Pathol 61: 577–587. doi: 10.1136/jcp.2007.048868
- 35. Allebban Z, Ichiki AT, Gibson LA, Jones JB, Congdon CC, et al. (1994) Effects of spaceflight on the number of rat peripheral blood leukocytes and lymphocyte subsets. J Leukoc Biol 55: 209–213.
- 36. Chapes SK, Simske SJ, Sonnenfeld G, Miller ES, Zimmerman RJ (1999) Effects of spaceflight and PEG-IL-2 on rat physiological and immunological responses. J Appl Physiol 86: 2065–2076.
- 37. Gashev AA, Delp MD, Zawieja DC (2006) Inhibition of active lymph pump by simulated microgravity in rats. Am J Physiol Heart Circ Physiol 290: H2295–2308. doi: 10.1152/ajpheart.00260.2005
- 38. Felix K, Wise K, Manna S, Yamauchi K, Wilson BL, et al. (2004) Altered cytokine expression in tissues of mice subjected to simulated microgravity. Mol Cell Biochem 266: 79–85. doi: 10.1023/b:mcbi.0000049136.55611.dd
- 39. Meloni MA, Galleri G, Pani G, Saba A, Pippia P, et al. (2011) Space flight affects motility and cytoskeletal structures in human monocyte cell line J-111. Cytoskeleton (Hoboken) 68: 125–137. doi: 10.1002/cm.20499
- 40. Sonnenfeld G (1999) Effects of space flight on surface marker expression. Adv Space Res 24: 815–820. doi: 10.1016/s0273-1177(99)00074-5
- 41. Ortega MT, Pecaut MJ, Gridley DS, Stodieck LS, Ferguson V, et al. (2009) Shifts in bone marrow cell phenotypes caused by spaceflight. J Appl Physiol 106: 548–555. doi: 10.1152/japplphysiol.91138.2008
- 42. Grove DS, Pishak SA, Mastro AM (1995) The effect of a 10-day space flight on the function, phenotype, and adhesion molecule expression of splenocytes and lymph node lymphocytes. Exp Cell Res 219: 102–109. doi: 10.1006/excr.1995.1210
- 43. Masuda H, Tsujimura A, Yoshioka M, Arai Y, Kuboki Y, et al. (1997) Bone mass loss due to estrogen deficiency is compensated in transgenic mice overexpressing human osteoblast stimulating factor-1. Biochem Biophys Res Commun 238: 528–533. doi: 10.1006/bbrc.1997.7188
- 44. Ichiki AT, Gibson LA, Jago TL, Strickland KM, Johnson DL, et al. (1996) Effects of spaceflight on rat peripheral blood leukocytes and bone marrow progenitor cells. J Leukoc Biol 60: 37–43.
- 45. Li G, Bunn JR, Mushipe MT, He Q, Chen X (2005) Effects of pleiotrophin (PTN) over-expression on mouse long bone development, fracture healing and bone repair. Calcif Tissue Int 76: 299–306. doi: 10.1007/s00223-004-0145-6
- 46. Husmann I, Soulet L, Gautron J, Martelly I, Barritault D (1996) Growth factors in skeletal muscle regeneration. Cytokine Growth Factor Rev 7: 249–258. doi: 10.1016/s1359-6101(96)00029-9
- 47. Dawson NJ (1972) Rate of passage of a non-absorbable marker through the gastrointestinal tract of the mouse (Mus musculus). Comp Biochem Physiol A Comp Physiol 41: 877–881. doi: 10.1016/0300-9629(72)90350-7
- 48. Liu Y, Biticchi R, Alberici G, Tenconi C, Cilli M, et al. (2005) Mouse Drawer System (MDS): An Autonomous Hardware for Supporting Mice Space Research. Journal of Gravitational Physiology 12: P291–292.
- 49. Rizzo AM, Corsetto PA, Montorfano G, Milani S, Zava S, et al. (2012) Effects of long-term space flight on erythrocytes and oxidative stress of rodents. PLoS one 7: e32361. doi: 10.1371/journal.pone.0032361
- 50. Masini MA, Albi E, Barmo C, Bonfiglio T, Bruni L, et al. (2012) The impact of long-term exposure to space environment on adult Mammalian organisms: a study on mouse thyroid and testis. PLoS one 7: e35418. doi: 10.1371/journal.pone.0035418
- 51. Sandona D, Desaphy JF, Camerino GM, Bianchini E, Ciciliot S, et al. (2012) Adaptation of mouse skeletal muscle to long-term microgravity in the MDS mission. PLoS one 7: e33232. doi: 10.1371/journal.pone.0033232
- 52. Callaway TR, Dowd SE, Wolcott RD, Sun Y, McReynolds JL, et al. (2009) Evaluation of the bacterial diversity in cecal contents of laying hens fed various molting diets by using bacterial tag-encoded FLX amplicon pyrosequencing. Poult Sci 88: 298–302. doi: 10.3382/ps.2008-00222
- 53. Abnous K, Brooks SP, Kwan J, Matias F, Green-Johnson J, et al. (2009) Diets enriched in oat bran or wheat bran temporally and differentially alter the composition of the fecal community of rats. J Nutr 139: 2024–2031. doi: 10.3945/jn.109.109470
- 54. Lane D (1991) 16S/23S rRNA sequencing; Stackebrandt E, Goodfellow M, editors. New York: John Wiley and Sons.
- 55. Sun Y, Cai Y, Liu L, Yu F, Farrell ML, et al. (2009) ESPRIT: estimating species richness using large collections of 16S rRNA pyrosequences. Nucleic Acids Res 37: e76. doi: 10.1093/nar/gkp285
- 56. Haas BJ, Gevers D, Earl AM, Feldgarden M, Ward DV, et al. (2011) Chimeric 16S rRNA sequence formation and detection in Sanger and 454-pyrosequenced PCR amplicons. Genome Res 21: 494–504. doi: 10.1101/gr.112730.110
- 57. Schloss PD, Westcott SL, Ryabin T, Hall JR, Hartmann M, et al. (2009) Introducing mothur: open-source, platform-independent, community-supported software for describing and comparing microbial communities. Appl Environ Microbiol 75: 7537–7541. doi: 10.1128/aem.01541-09
- 58. Galtier N, Gouy M, Gautier C (1996) SEAVIEW and PHYLO_WIN: two graphic tools for sequence alignment and molecular phylogeny. Comput Appl Biosci 12: 543–548. doi: 10.1093/bioinformatics/12.6.543
- 59. Jukes T, Cantor C (1996) Evolution of protein molecules; Munro HN, editor. New York: Academic Press. 21–132 p.
- 60. Wang Q, Garrity GM, Tiedje JM, Cole JR (2007) Naive Bayesian classifier for rapid assignment of rRNA sequences into the new bacterial taxonomy. Appl Environ Microbiol 73: 5261–5267. doi: 10.1128/aem.00062-07
- 61. Beals E (1984) Bray-Curtis ordination: an effective strategy for analysis of multivariate ecological data.; MacFadyen A, Ford E, editors. London: Academic Press.