ALBERT

Description: To study the complex pathophysiology of aGvHD in allogeneic hematopoietic cell transplantation (HCT) we transplanted transgenic luciferase expressing T cell populations into lethally irradiated HCT recipients (murine MHC major mismatch model, H-2q into H-2d). Tracking of light emitting donor T cells in living animals and detailed studies by multi color immunofluorescence microscopy (IFM) and FACS revealed the tight links of spatial and temporal evolution in this complex immune process. Donor derived T cells migrate to T cell areas in lymphoid tissues within a period of 12 hours. In the initial periods donor CD4+ T cells appear first with CD8+ T cell infiltration at later time points. Donor T cells start proliferating in lymphatic tissues on day 2 after transfer, as observed by BrdU stainings. Although alloreactive T cells are similarly activated in all lymphoid organs, they only up-regulate gut homing molecules after more than 5 cell divisions (CFSE proliferation analysis by FACS) in certain lymphoid organs (Peyer’s patches, mesenteric LN and spleen). Abruptly on day 4 after HCT, T cells migrate into intestinal sites. These findings strongly suggested, that specific priming sites are required for alloreactive T cells to induce a distinct type of tissue tropism in GvHD. In contrast to previous reports peformed without host conditioning, depletion of certain lymphoid organs (e.g. Peyer’s patches) before HCT or antibody blocking experiments did not control aGVHD. BLI showed, that anti-L-selectin or anti-MAdCAM-1 antibody treatment alone or in combination was effective in blocking donor T cell migration to lymph nodes and Peyer’s patches, while redirecting these cells to liver and spleen. Subsequently cells proliferated predominantly in the spleen until day 3 after HCT. Surprisingly we observed a full picture of gut infiltration on day 4 and skin involvement on day 5–6, similar in dynamics and strength to the aGvHD isotype control group. These findings demonstrated, that other lymphoid organs can functionally compensate for inducing gut and skin homing of alloreactive T cells. Of importance, we demonstrated that T cells that lacked homing molecules for secondary lymphoid organs had alloreactive properties in vitro, yet did not cause aGVHD in vivo. In summary, the activation of alloreactive T cells in specific sites throughout the body is complex and involves the acquisition of homing molecule expression. Transplantation of T cells with defined homing properties therefore, appears to be a promising alternative in conferring protective immunity early after HCT without the risk of aGvHD.

Description: Abstract 2451 Poster Board II-428 Hematopoietic cell transplantation (HCT) is a curative therapy for a variety of malignancies. HCT provides disease eradication through both the high-dose conditioning regimen and an allogeneic graft versus tumor effect (GVT), however graft-versus-host disease (GVHD) remains a major obstacle. In a murine aHCT model of bioluminescence imaging (BLI) we have previously demonstrated that acute GVHD can be separated to a GVHD initiation phase confined to secondary lymphoid organs and a subsequent GVHD effector phase in peripheral target tissues. It has been proposed that host conditioning may not only be crucial in the activation of alloreactive T cells but also determine acute GVHD organ manifestation in the effector phase. Here we wanted to investigate how the host conditioning regimen affects the host target tissues in terms of inflammatory cytokines and their role in donor T cell recruitment. We compared lethally irradiated (8Gy) vs. non-irradiated Balb/c wild type or Balb/c Rag-/-cGC-/- (H-2d) -DKO mice that received allogeneic luciferase+ FVB/N T cells (H-2q). Surprisingly, we did not observe marked differences in the donor T cell proliferation (BLI, CFSE), acquisition of activation markers (CD25, CD44, CD69) and homing receptors (a4b7, aEb7, P-selectin ligand, E-selecting ligand) in conditioned, non-conditioned Balb/c Rag-/-cGC-/-. Despite the upregulation of these homing receptors on donor T cells, infiltration of target tissues (intestinal tract, liver and skin) was significantly accelerated in conditioned and delayed in non-conditioned hosts. As T cell recruitment may have occurred as a result of alterations of the milieu inflammatory cytokines in GVHD target tissues, we compared the cytokine profile in conditioned vs. non-conditioned recipients. At days 3 and 6 after transplantation tissues were harvested and cytokines from the target tissues; liver, large bowel, small bowel, peripheral blood and a non target tissue: kidney were analyzed for a TH1/TH2/Th17a cytokines. At day 3 high levels of INF-γ and TNF were detected in the Balb/c WT conditioned host compared to the non-conditioned host in all target tissues (SB, LB, and liver) and most markedly in peripheral blood and the large bowel. More importantly the Balb/c Rag-/-cGC-/- conditioned host displayed about 5 times higher levels of both inflammatory cytokines compared to the non conditioned DKO hosts and to the Balb/c WT. Similar results with a lesser levels were observed both for IL-2 and IL17a. By day 6 similar results are seen but with a much reduced expression of the cytokines, indicating that the cytokine storm peak was maybe at day 3. In summary host conditioning is not a requirement for alloreactive T cell activation rather induced inflammatory cytokines such as TNF and INF-γ are the determinant factors for effector T cell recruitment to GVHD target tissues. JB and AB contributed equally to this work. Disclosures: No relevant conflicts of interest to declare.

Description: In acute graft-versus-host disease (aGVHD), donor T cells attack the recipient's gastrointestinal tract, liver, and skin. We hypothesized that blocking access to distinct lymphoid priming sites may alter the specific organ tropism and prevent aGVHD development. In support of this initial hypothesis, we found that different secondary lymphoid organs (SLOs) imprint distinct homing receptor phenotypes on evolving alloreactive effector T cells in vivo. Yet preventing T-cell entry to specific SLOs through blocking monoclonal antibodies, or SLO ablation, did not alter aGVHD pathophysiology. Moreover, transfer of alloreactive effector T cells into conditioned secondary recipients targeted the intestines and liver, irrespective of their initial priming site. Thus, we demonstrate redundancy of SLOs at different anatomical sites in aGVHD initiation. Only prevention of T-cell entry to all SLOs could completely abrogate the onset of aGVHD.

Description: Graft-versus-host disease (GVHD) is a major obstacle in allogeneic hematopoietic cell transplantation. Given the dynamic changes in immune cell subsets and tissue organization, which occur in GVHD, localization and timing of critical immunological events in vivo may reveal basic pathogenic mechanisms. To this end, we transplanted luciferase-labeled allogeneic splenocytes and monitored tissue distribution by in vivo bioluminescence imaging. High-resolution analyses showed initial proliferation of donor CD4+ T cells followed by CD8+ T cells in secondary lymphoid organs with subsequent homing to the intestines, liver, and skin. Transplantation of purified naive T cells caused GVHD that was initiated in secondary lymphoid organs followed by target organ manifestation in gut, liver, and skin. In contrast, transplanted CD4+ effector memory T (TEM) cells did not proliferate in secondary lymphoid organs in vivo and despite their in vitro alloreactivity in mixed leukocyte reaction (MLR) assays did not cause acute GVHD. These findings underline the potential of T-cell subsets with defined trafficking patterns for immune reconstitution without the risk of GVHD.

Description: Acute graft-versus-host disease (aGVHD) results from alloreactive donor derived T cells attacking targets in the gastrointestinal tract, liver and skin. We observed the initiation and rapid kinetics of aGVHD in a murine model [FVB/N (H-2q) into irradiated Balb/c (H-2d)] using in vivo bioluminescence imaging. The transition from the initiation to the effector phase of aGVHD (day 3–4) was characterized by rapid T cell proliferation and upregulation of gut homing receptors alpha4beta7, alphaEbeta7 and CCR9 on alloreactive T cells in Peyer’s patches (PP), mesenteric lymph nodes (LN) and spleen, but not peripheral LNs. Therefore we asked whether the lack of specific lymphoid priming sites would lead to decreased alloreactive T cell infiltration in the gut compared to the liver and skin. Using PP deficient mice, we observed that mesenteric LN and spleen compensate for the lack of PP as alloreactive priming sites. Transplantation of PP and LN deficient mice (TNFalpha-/-) showed that the spleen alone was sufficient to cause the complete profile of aGVHD with a time course similar to that of wildtype mice. Splenectomized mice with intact secondary lymphoid organs also developed aGVHD. Strikingly, treatment of splenectomized recipients with blocking antibodies against the lymphoid homing receptors L-selectin and MAdCAM-1 prevented GVHD with 100% survival (〉120 d, p

Description: Acute graft-versus-host disease (aGVHD) is caused by alloreactive effector T cells attacking the gastrointestinal tract, liver and skin after allogeneic hematopoietic cell transplantation (aHCT). The mechanism by which alloreactive T cells target these organs and not others remains elusive. Recently, we reported that different secondary lymphoid organs (SLOs), as alloreactive priming sites, can imprint distinct homing phenotypes on evolving alloreactive effector cells in vivo. However, preventing access to selected lymphoid organs (via the use of blocking antibodies or recipient mice lacking Peyer’s patches (PP), PP and lymph nodes (LN) or spleens) did not alter the aGVHD organ manifestation. These findings not only suggested a high redundancy of SLOs as induction sites of aGVHD, but also questioned whether homing instruction of alloreactive T cells by these sites can explain the mechanism of aGVHD target organ manifestation. To test the homing instruction model we transplanted transgenic luciferase+ (luc+) FVB/N (H-2q, Thy1.1+) splenocytes into conditioned (2×400rad) Balb/c recipients (H-2d, Thy1.2+). On day+3 we isolated luc+ donor lymphocytes from peripheral LN, mesenteric LN, or spleens and transferred them into conditioned secondary allogeneic recipients. 16 hours later, bioluminescence imaging revealed that allogeneic luc+ T cells irrespective of their original priming site targeted the intestinal tract and liver. Subsequently, we compared aHCT of conditioned with non-conditioned secondary Balb/cRag−/− cγ-Chain−/− recipients. Surprisingly, we found allogeneic luc+ T cells accumulating in SLOs in non-conditioned recipients in contrast to intestinal and hepatic tissues in conditioned recipients. These in vivo findings establish that alloreactive effector cells migrate to aGVHD target tissues because of attraction to these sites rather than specific instruction by SLOs. Therefore, we propose a signal hierarchy model of alloreactive cell trafficking whereby inflammatory signal/ligand interactions dominate over organ-specific homing receptor/ligand interactions.

Description: The ESA Earth Explorer CryoSat-2 was launched on 8 April 2010 to monitor the precise changes in the thickness of terrestrial ice sheets and marine floating ice. To do that, CryoSat orbits the planet at an altitude of around 720 km with a retrograde orbit inclination of 92∘ and a quasi repeat cycle of 369 d (30 d subcycle). To reach the mission goals, the CryoSat products have to meet the highest quality standards to date, achieved through continual improvements of the operational processing chains. The new CryoSat Ice Baseline-D, in operation since 27 May 2019, represents a major processor upgrade with respect to the previous Ice Baseline-C. Over land ice the new Baseline-D provides better results with respect to the previous baseline when comparing the data to a reference elevation model over the Austfonna ice cap region, improving the ascending and descending crossover statistics from 1.9 to 0.1 m. The improved processing of the star tracker measurements implemented in Baseline-D has led to a reduction in the standard deviation of the point-to-point comparison with the previous star tracker processing method implemented in Baseline-C from 3.8 to 3.7 m. Over sea ice, Baseline-D improves the quality of the retrieved heights inside and at the boundaries of the synthetic aperture radar interferometric (SARIn or SIN) acquisition mask, removing the negative freeboard pattern which is beneficial not only for freeboard retrieval but also for any application that exploits the phase information from SARIn Level 1B (L1B) products. In addition, scatter comparisons with the Beaufort Gyre Exploration Project (BGEP; https://www.whoi.edu/beaufortgyre, last access: October 2019) and Operation IceBridge (OIB; Kurtz et al., 2013) in situ measurements confirm the improvements in the Baseline-D freeboard product quality. Relative to OIB, the Baseline-D freeboard mean bias is reduced by about 8 cm, which roughly corresponds to a 60 % decrease with respect to Baseline-C. The BGEP data indicate a similar tendency with a mean draft bias lowered from 0.85 to −0.14 m. For the two in situ datasets, the root mean square deviation (RMSD) is also well reduced from 14 to 11 cm for OIB and by a factor of 2 for the BGEP. Observations over inland waters show a slight increase in the percentage of good observations in Baseline-D, generally around 5 %–10 % for most lakes. This paper provides an overview of the new Level 1 and Level 2 (L2) CryoSat Ice Baseline-D evolutions and related data quality assessment, based on results obtained from analyzing the 6-month Baseline-D test dataset released to CryoSat expert users prior to the final transfer to operations.

Description: The terrestrial subsurface is the largest source of freshwater globally. The organic carbon contained within it and processes controlling its concentration remain largely unknown. The global median concentration of dissolved organic carbon (DOC) in groundwater is low compared to surface waters, suggesting significant processing in the subsurface. Yet the processes that remove this DOC in groundwater are not fully understood. The purpose of this study was to investigate the different sources and processes influencing DOC in a shallow anoxic coastal aquifer. Uniquely, this study combines liquid chromatography organic carbon detection with organic (δ13CDOC) carbon isotope geochemical analyses to fingerprint the various DOC sources that influence the concentration, carbon isotopic composition, and character with respect to distance from surface water sources, depth below surface, and inferred groundwater residence time (using 3H activities) in groundwater. It was found that the average groundwater DOC concentration was 5 times higher (5 mg L−1) than the global median concentration and that the concentration doubled with depth at our site, but the chromatographic character did not change significantly. The anoxic saturated conditions of the aquifer limited the rate of organic matter processing, leading to enhanced preservation and storage of the DOC sources from peats and palaeosols contained within the aquifer. All groundwater samples were more aromatic for their molecular weight in comparison to other lakes, rivers and surface marine samples studied. The destabilization or changes in hydrology, whether by anthropogenic or natural processes, could lead to the flux of up to 10 times more unreacted organic carbon from this coastal aquifer compared to deeper inland aquifers.

Description: Multiple observation data sets – Interagency Monitoring of Protected Visual Environments (IMPROVE) network data, the Automated Smoke Detection and Tracking Algorithm (ASDTA), Hazard Mapping System (HMS) smoke plume shapefiles and aircraft acetonitrile (CH3CN) measurements from the NOAA Southeast Nexus (SENEX) field campaign – are used to evaluate the HMS–BlueSky–SMOKE (Sparse Matrix Operator Kernel Emission)–CMAQ (Community Multi-scale Air Quality Model) fire emissions and smoke plume prediction system. A similar configuration is used in the US National Air Quality Forecasting Capability (NAQFC). The system was found to capture most of the observed fire signals. Usage of HMS-detected fire hotspots and smoke plume information was valuable for deriving both fire emissions and forecast evaluation. This study also identified that the operational NAQFC did not include fire contributions through lateral boundary conditions, resulting in significant simulation uncertainties. In this study we focused both on system evaluation and evaluation methods. We discussed how to use observational data correctly to retrieve fire signals and synergistically use multiple data sets. We also addressed the limitations of each of the observation data sets and evaluation methods.

Description: Snow densification stores water in alpine regions and transforms snow into ice on the surface of glaciers. Despite its importance in determining snow-water equivalent and glacier-induced sea level rise, we still lack a complete understanding of the physical mechanisms underlying snow compaction. In essence, compaction is a rheological process, where the rheology evolves with depth due to variation in temperature, pressure, humidity, and meltwater. The rheology of snow compaction can be determined in a few ways, for example, through empirical investigations (e.g., Herron and Langway, 1980), by microstructural considerations (e.g., Alley, 1987), or by measuring the rheology directly, which is the approach we take here. Using a French-press or cafetière-à-piston compression stage, Wang and Baker (2013) compressed numerous snow samples of different densities. Here we derive a mixture theory for compaction and airflow through the porous snow to compare against these experimental data. We find that a plastic compaction law explains experimental results. Taking standard forms for the permeability and effective pressure as functions of the porosity, we show that this compaction mode persists for a range of densities and overburden loads. These findings suggest that measuring compaction in the lab is a promising direction for determining the rheology of snow through its many stages of densification.