Fructosyl transfer from sucrose and oligosaccharides during fructan synthesis in excised leaves of Lolium temulentum L.

Fructan biosynthesis begins with the transfer of a fructosyl moiety from one sucrose molecule to another to yield a trisaccharide. Trisaccharides may also arise by the reversible transfer of a fructosyl moiety from higher oligomers to sucrose but in this case there is no net fructan synthesis. Short‐term and long‐term exposure of detached illuminated leaf blades of Lolium temulentum (L.I to 14CO2 was used to examine the mechanism of transfer of fructosyl residues to sucrose. Two trisaccharides, 1‐kestose and neokestose, were found to be radioactive when leaves excised and illuminated for 15 h ‐were exposed to NCO2 for 30 min. The label increased in neokestose during the chase period, while that in 1‐kestose increased for the first 2 h of the chase period then declined for the remaining 4h. With a longer exposure to 14CO2 during the first 6 h of the induction period, three trisaccharides, neokestose, 1‐kestose and 6‐kestose were radiolabelled. The label turned over in neokestose and 1‐kestose, but continued to accumulate in 6‐kestose during a subsequent 18 h chase period. The specific activities of glucose and fructose of the sucrosyl portion and the terminal fructosyl moiety of the various trisaccharides were compared. In the rapid pulse‐chase experiment the specific activity of the1 terminal fructosyl moiety was consistently less than that of the sucrosyl moiety. During the chase period, the specific activity of the terminal and internal fructose moieties became similar. These results indicate that in addition to trisaccharide formed by transfer of fructosyl units from sucrose, substantial amounts of both neokestose and 1‐kestose are made by transfer of fructosyl units from higher oligomers onto sucrose in reactions probably localized in the vacuole. Copyright © 1991, Wiley Blackwell. All rights reserved

Fructosyl transfer from sucrose and oligosaccharides during fructan synthesis in excised leaves of Lolium temulentum L.

Fructan biosynthesis begins with the transfer of a fructosyl moiety from one sucrose molecule to another to yield a trisaccharide. Trisaccharides may also arise by the reversible transfer of a fructosyl moiety from higher oligomers to sucrose but in this case there is no net fructan synthesis. Short‐term and long‐term exposure of detached illuminated leaf blades of Lolium temulentum (L.I to 14CO2 was used to examine the mechanism of transfer of fructosyl residues to sucrose. Two trisaccharides, 1‐kestose and neokestose, were found to be radioactive when leaves excised and illuminated for 15 h ‐were exposed to NCO2 for 30 min. The label increased in neokestose during the chase period, while that in 1‐kestose increased for the first 2 h of the chase period then declined for the remaining 4h. With a longer exposure to 14CO2 during the first 6 h of the induction period, three trisaccharides, neokestose, 1‐kestose and 6‐kestose were radiolabelled. The label turned over in neokestose and 1‐kestose, but continued to accumulate in 6‐kestose during a subsequent 18 h chase period. The specific activities of glucose and fructose of the sucrosyl portion and the terminal fructosyl moiety of the various trisaccharides were compared. In the rapid pulse‐chase experiment the specific activity of the1 terminal fructosyl moiety was consistently less than that of the sucrosyl moiety. During the chase period, the specific activity of the terminal and internal fructose moieties became similar. These results indicate that in addition to trisaccharide formed by transfer of fructosyl units from sucrose, substantial amounts of both neokestose and 1‐kestose are made by transfer of fructosyl units from higher oligomers onto sucrose in reactions probably localized in the vacuole. Copyright © 1991, Wiley Blackwell. All rights reserved

Manganese transport and toxicity in polarized WIF-B hepatocytes

Manganese (Mn) toxicity arises from nutritional problems, community and occupational exposures, and genetic risks. Mn blood levels are controlled by hepatobiliary clearance. The goals of this study were to determine the cellular distribution of Mn transporters in polarized hepatocytes, to establish an in vitro assay for hepatocyte Mn efflux, and to examine possible roles the Mn transporters would play in metal import and export. For these experiments, hepatocytoma WIF-B cells were grown for 12–14 days to achieve maximal polarity. Immunoblots showed that Mn transporters ZIP8, ZnT10, ferroportin (Fpn), and ZIP14 were present. Indirect immunofluorescence microscopy localized Fpn and ZIP14 to WIF-B cell basolateral domains whereas ZnT10 and ZIP8 associated with intracellular vesicular compartments. ZIP8-positive structures were distributed uniformly throughout the cytoplasm, but ZnT10-positive vesicles were adjacent to apical bile compartments. WIF-B cells were sensitive to Mn toxicity, showing decreased viability after 16 h exposure to >250 μM MnCl2. However, the hepatocytes were resistant to 4-h exposures of up to 500 μM MnCl2 despite 50-fold increased Mn content. Washout experiments showed time-dependent efflux with 80% Mn released after a 4 h chase period. Hepcidin reduced levels of Fpn in WIF-B cells, clearing Fpn from the cell surface, but Mn efflux was unaffected. The secretory inhibitor, brefeldin A, did block release of Mn from WIF-B cells, suggesting vesicle fusion may be involved in export. These results point to a possible role of ZnT10 to import Mn into vesicles that subsequently fuse with the apical membrane and empty their contents into bile. NEW & NOTEWORTHY Polarized WIF-B hepatocytes express manganese (Mn) transporters ZIP8, ZnT10, ferroportin (Fpn), and ZIP14. Fpn and ZIP14 localize to basolateral domains. ZnT10-positive vesicles were adjacent to apical bile compartments, and ZIP8-positive vesicles were distributed uniformly throughout the cytoplasm. WIF-B hepatocyte Mn export was resistant to hepcidin but inhibited by brefeldin A, pointing to an efflux mechanism involving ZnT10-mediated uptake of Mn into vesicles that subsequently fuse with and empty their contents across the apical bile canalicular membrane.

Nitrogen Uptake and Allocation at Different Growth Stages of Young Southern Highbush Blueberry Plants

Southern highbush blueberry (SHB, Vaccinium corymbosum L. interspecific hybrid) is the major species planted in Florida because of the low-chilling requirement and early ripening. The growth pattern and nitrogen (N) demand of SHB may differ from those of northern highbush blueberry (NHB, V. corymbosum L.). Thus, the effect of plant growth stage on N uptake and allocation was studied with containerized 1-year-old SHB grown in pine-bark amended soil. Five ‘Emerald’ plants were each treated with 6 g 10% 15N labeled (NH4)2SO4 at each of 12 dates over 2 years. In the first year, plants were treated once in late winter, four times during the growing season, and once in the fall. In the second year, treatment dates were based on phenological stages. After a 14-day chase period following each 15N treatment, plants were destructively harvested for dry weight (DW) measurements, atom% of 15N, and N content of each of the plant tissues. Total DW increased continuously from mid-May 2015 to Oct. 2015 and from Mar. 2016 to late Sept. 2016. From August to October of both years, external N demand was the greatest and plants absorbed more N during the 2-week chase period, about 0.53 g/plant in year 1 and 0.67 g/plant in year 2, than in chase periods earlier in the season. During March and April, N uptake was as low as 0.03 g/plant/2 weeks in year 1 and 0.21 g/plant/2 weeks in year 2. Nitrogen allocation to each of the tissues varied throughout the season. About half of the N derived from the applied fertilizer was allocated to leaves at all labeling times except the early bloom stage in 2016. These results suggest that young SHB plants absorb greater amounts of N during summer and early fall than in spring.

Abstract 218: Cardiac Side Population Cells Give Rise to Cardiomyocytes in the Adult Heart

Therapies that enhance cardiac regeneration have the potential to improve heart failure outcomes. One strategy to enhance cardiac regeneration is by activating endogenous cardiac progenitor cells. Cardiac side population cells (cSPCs) are proposed progenitor cells that reside in the heart; however, their putative progenitor cell properties are based on cell culture data and transplantation studies performed with isolated cSPCs. To determine the endogenous regenerative potential of cSPCs in vivo , we generated a mouse model that harbors an Abcg2-driven, tamoxifen-inducible Cre recombinase and crossed it to a GFP reporter mice. One month after tamoxifen treatment, we obtained efficient GFP-labeling of side population cells with 47.0 ± 11.05% of bone marrow side population cells and 75.8 ± 10.87% of cSPCs. Importantly, during a one-month chase period, we observed a three-fold increase in GFP-labeled cardiomyocytes when compared to a 1-week chase period. We quantified the extent of GFP-labeling of cardiomyocytes using adult cardiomyocyte isolation, where we measured 0.8% GFP labeled cardiomyocytes after a one-month chase period. We also observed labeling of many other cell types in the heart, such as endothelial cells, smooth muscle cells, and pericytes. We are currently testing to what extent cardiac injury enhances cSPC derived cardiomyocyte formation. Using our mouse model that efficiently labels side population cells in vivo , we demonstrated that cSPCs contribute cardiomyocytes in the adult heart in vivo .

Distinct populations of label-retaining cells in the adult kidney are defined temporally and exhibit divergent regional distributions

DNA label-retention, or retention of a thymidine analog, is a characteristic of slow cycling cells and has been used to identify stem cells in several organ systems. Recent findings have demonstrated inconsistent localization of label-retaining cells (LRCs) in the kidney. Differences in the dose and timing of administration of deoxyuridine, the length of the chase period, and the species of animal used have made understanding the distinctions between these findings difficult. In the present studies, we utilized a dual loading scheme in the same animal to demonstrate that the cells labeled at different ages identified independent populations of LRC that distributed globally in an anti-parallel manner in the kidney. Loading with a DNA label in neonates identified LRC more often in the papilla, while administering the DNA label in adult mice identified LRC prominently in the cortex and the outer medulla. Furthermore, the tissue compartment distribution (epithelial-endothelial-interstitial) as well as the specific distribution within the nephron epithelia differed for these populations. These findings highlighted the complexity of the dynamics of cell proliferation in the kidney throughout the postnatal and adult period and call attention to the confusion associated with the term “label-retaining cells” for different timings of the loading and chase periods. This study indicated that the results of previous studies should be viewed as nonoverlapping and that further studies are needed to ascertain the role of each of these populations in the steady-state maintenance and injury recovery of the kidney.

Abstract 284: Cholesterol Handling in Bone Marrow--Derived Macrophages from Apoe-Deficient AKR and DBA/2 Mice

It has been demonstrated in humans that about 50% of the susceptibility to atherosclerosis is heritable. Therefore, it is not surprising that mice from distinct genetic backgrounds present different susceptibility to atherosclerosis. For example, apoE -/- DBA/2 mice have aortic root atherosclerosis lesion areas >10-fold larger than apoE -/- AKR mice. In order to better understand the mechanisms underlying this difference, we studied cholesterol metabolism in bone marrow-derived macrophages from these two strains. In the unloaded state, macrophages from both strains had equivalent amounts of total, esterified, and free cholesterol (TC, CE, and FC, respectively). Cells were loaded with acetylated low density lipoproteins (AcLDL) for 48h and DBA/2 macrophages had 36% higher TC (p<0.0001) vs. AKR macrophages, mainly due to 72% higher CE accumulation (p<0.0001). In contrast the loaded DBA/2 macrophages had 6% lower FC than the AKR macrophages (p<0.05). No difference was seen in AcLDL uptake or acetyl-coenzyme A acyltransferase (ACAT) activity between the two strains. When cells were loaded with AcLDL, the DBA/2 cells released cholesterol less efficiently than the AKR cells to apoAI (18% lower, p=0.01) or HDL (25% lower, p=0.001). However when the loading was performed in presence of ACAT inhibitor, blocking the formation of CE, the efflux from the two strains was equivalent suggesting a blockage of CE hydrolysis in DBA/2 cells. In loaded cells, when a 24h chase period was done in presence of ACAT inhibitor to prevent cholesterol re-esterification, the CE was reduce by 69% in AKR cells (t 1/2 = 47h) compared to chase without inhibitor while it was only reduced by 42% in DBA/2 cells (t 1/2 = 101h). Furthermore, when lalistat, an inhibitor of lysosomal acid lipase (LAL), and ACAT inhibitor were added during the chase, CE levels were equivalent to the one observed in chase without any inhibitors, suggesting that CE hydrolysis occurs primarily in the lysosome. In conclusion, our data support the hypothesis that DBA/2 cells accumulate more CE than AKR cells due to a defect in CE hydrolysis by LAL. Autophagy has been recently described as the pathway in macrophages by which lipid droplets can be delivered to the lysosome, and we are investigating the role of this pathway in our cells.

Hematopoietic Stem Cells Mediate the Repair of Damaged Endothelium

Recent studies indicate that vascular endothelium is an important component of the hematopoietic niche. As endothelial cells (ECs) are sensitive to radiation-induced damage, we evaluated the potential role of hematopoietic stem cells to enhance EC proliferation and repair. To test this hypothesis, lethally irradiated mice were transplanted with either 200–500 c-kit+, Sca+, lineage- (KSL) cells or an equivalent dose of unfractionated bone marrow (BM) cells (1×106 cells). Control groups included irradiated, non-transplanted, and non-irradiated, non-transplanted mice. Immediately after irradiation, all recipients were maintained on 0.8mg/ml Bromodeoxyuridine (BrdU) -containing water. Eleven days following irradiation, liver tissue was harvested and the fraction of proliferating BrdU+ ECs in the portal vein was assessed by immunostaining using both light and fluorescence microscopy. In irradiated, non-transplanted mice, 0.95% ± 0.17 SEM of portal vein ECs demonstrated the incorporation of BrdU. Transplantation of KSL cells increased the frequency of proliferating endothelial cells 2.5-fold to 2.5% ± 0.20 (p&lt;0.0006). The transplantation of an equivalent number of unfractionated BM cells further increased the frequency of proliferating ECs by more than 3.5-fold (3.75% ± 0.21; p&lt;0.0005). In non-transplanted, non-irradiated mice, BrdU+ ECs were detected at an intermediate level (2.30% ± 0.24) that is significantly higher than irradiated nontransplant recipients (p&lt;0.006). To gain a better understanding of how hematopoietic stem cells (HSCs) influence the label retention capacity of ECs, we performed a BrdU pulse-chase experiment. Lethally irradiated mice were transplanted with 200 KSL cells, allowed 4 weeks for recovery, and then maintained on BrdU drinking water for 4 weeks. Consistent with our findings from the short term experiment described above, significantly more BrdU+ ECs were detected in the portal veins of KSL transplanted mice (15.36% ± 2.07) compared to those in non-transplanted, non-irradiated mice (8.68% ± 0.54; p&lt;0.04) at the start of the chase period. During the first 24 weeks of the washout phase, BrdU+ ECs declined at a greater rate in the KSL recipients than in controls, indicating increased EC turnover. Interestingly, however, in both experimental groups, BrdU retention plateaued at 24 weeks and remained constant through 36 weeks. Taken together, our results indicate that radiation damage suppresses the incorporation of BrdU into ECs compared to steady state conditions and that this suppression can be reversed by the transplantation of either hematopoietic stem cells or unfractionated bone marrow. The extent to which BM derived ECs contribute to the proliferating EC pool will be addressed in future studies.

Label-retaining cells of the bladder: candidate urothelial stem cells

Adult tissue stem cells replicate infrequently, retaining DNA nucleotide label (BrdU) for much longer periods than mature, dividing cells in which the label is diluted during a chase period. Those “label-retaining cells” (LRCs) have been identified as the tissue stem cells in skin, cornea, intestine, and prostate. However, in the urinary tract uroepithelial stem cells have not yet been identified. In this study, BrdU administration identified urothelial LRCs in the rat bladder with 9% of the epithelial basal cells retaining BrdU label 1 yr after its administration. Markers for stem cells in other tissues, Bcl, p63, cytokeratin 14, and β1 integrin, were immunolocalized in the basal bladder epithelium in or near urothelial LRCs, but not uniquely limited to these cells. Flow cytometry demonstrated that urothelial LRCs were small, had low granularity, and were uniquely β4 integrin bright. Urothelium from long-term labeled bladders was cultured and LRCs were found to be significantly more clonogenic and proliferative, characteristics of stem cells, than unlabeled urothelial cells. Thus, this work demonstrates that LRCs in the bladder localize to the basal layer, are small, low granularity, uniquely β4 integrin rich, slowly cycling and demonstrate superior clonogenic and proliferative ability compared with unlabeled epithelial cells. We propose that LRCs represent putative urothelial stem cells.