Yoshinori Maeshima

Effects of L-Arginine Infusion During Ischemia on Gut Blood Perfusion, Oxygen Tension, and Circulating Myeloid Cell Activation in a Murine Gut Ischemia/Reperfusion Model

BACKGROUND Gut hypoperfusion is considered to be a mechanism for early multiple-organ failure after severe surgical insults. L-Arginine (ARG) may preserve gut microcirculation as a substrate of nitric oxide synthase, but simultaneously may enhance immune cell response. It remains unknown if ARG infusion during gut ischemia improves the outcome after gut ischemia-reperfusion (I/R). METHODS Male Institute of Cancer Research mice were randomized to control and ARG groups. After i.v. cannulation, mice underwent 90 (Exp. 1) or 60 (Exp. 2 and 3) minutes of gut I/R. Control mice received normal saline infusion at 1 mL/h for 60 minutes during ischemia, whereas the ARG group was given 1% ARG hydrochloride solution. In Exp. 1, survival was observed for 72 hours (n = 35). In Exp. 2, blood perfusion and oxygen tension of the small intestine were measured (n = 9). In Exp. 3, peripheral blood was obtained at 2 or 4 hours after reperfusion (n = 22). Reactive oxygen intermediate (ROI) production by myeloid cells with or without phorbol myristate acetate (PMA) stimulation and expression of CD11a and CD11b on myeloid cells were examined using flow cytometry. RESULTS Exp. 1: There was no significant difference in survival times (log rank test, p = .2). However, survival rates at 12 hours were 72% (13/18) for the control group and 35% (6/17) for the ARG group (p < .05 Fisher). Exp. 2: ARG infusion significantly improved gut blood perfusion ratio during ischemia but had no effect on oxygen tension. Exp. 3: In the ARG group, ROI production with PMA and CD11b expression at 4 hours were higher than those at 2 hours, whereas there were no significant changes in the control mice. CONCLUSIONS ARG infusion improves intestinal blood perfusion during ischemia but primes and activates circulating myeloid cells excessively. Consequently, i.v. infusion of ARG during ischemia reduces survival rate.

Intestinal polymeric immunoglobulin receptor is affected by type and route of nutrition.

BACKGROUND Secretory immunoglobulin A (SIgA) prevents adherence of pathogens at mucosal surfaces to prevent invasive infection. Polymeric immunoglobulin receptor (pIgR) is located on the basolateral surface of epithelial cells and binds dimeric immunoglobulin A (IgA) produced by plasma cells in the lamina propria. This IgA-pIgR complex is transported apically, where IgA is exocytosed as SIgA to the mucosal surface. Our prior work shows that mice fed intragastric (IG, an elemental diet model) and IV parenteral nutrition (PN) solution have reduced intestinal T and B cells, SIgA, and interleukin-4 (IL-4) compared with mice fed chow or a complex enteral diet (CED). Prior work also demonstrates a reduction in IgA transport to mucosal surfaces in IV PN-fed mice. Because IL-4 up-regulates pIgR production, this work studies the effects of these diets on intestinal pIgR. METHODS Male Institute of Cancer Research (ICR) mice were randomized to chow (n = 11) with IV catheter, CED (n = 10) or IG PN (n = 11) via gastrostomy and IV PN (n = 12) for 5 days. CED and PN were isocaloric and isonitrogenous. Small intestine was harvested for pIgR and IL-4 assays after mucosal washing for IgA. IgA and IL-4 levels were analyzed by enzyme-linked immunosorbent assay and pIgR by Western blot. RESULTS Small intestinal pIgR expression, IgA levels, and IL-4 levels decreased significantly in IV PN and IG PN groups. CONCLUSIONS Lack of enteral stimulation affects multiple mechanisms responsible for decreased intestinal SIgA levels, including reduced T and B cells in the lamina propria, reduced Th-2 IgA-stimulating cytokines, and impaired expression of the IgA transport protein, pIgR.

Exogenous interleukin 7 affects gut-associated lymphoid tissue in mice receiving total parenteral nutrition.

In the absence of enteral nutrient delivery, gut-associated lymphoid tissue (GALT) mass and function are reduced. The purpose of this study was to examine whether exogenous interleukin (IL)-7 treatment reverses intravenous (IV)-total parenteral nutrition (TPN)-induced changes in GALT, immunoglobulin (Ig) A levels, and gut barrier function. Eighty-nine mice were randomized to chow, TPN, or TPN + IL-7 (1 μg/kg, administered IV twice a day) and treated for 5 days. The entire small intestine was harvested and lymphocytes were isolated from Peyers patches (PPs), intraepithelial (IE) spaces, and the lamina propria (LP). Small intestinal and bronchoalveolar IgA levels were measured. Proximal and distal small intestinal levels of IgA-stimulating (IL-10) and IgA-inhibiting (IFNγ) cytokines were determined with enzyme-linked immunoabsorbant assay. Moreover, 1 × 1010 live Pseudomonas aeruginosa were delivered by gavage and survival was observed. TPN decreased total cell yields from PPs, IE spaces, and the LP compared with the chow group. IL-7 treatment restored cell numbers. PP CD4+, PP CD8+, IE γδTCR+, and LP CD4+ cell numbers were higher in the TPN + IL-7 group than in the TPN group. Secretory IgA levels were lower in the TPN and TPN + IL-7 than in the chow group. In the distal small intestine, IFNγ levels were similar in the three groups, whereas IL-10 levels were reduced in the TPN and TPN + IL-7 groups relative to the chow group. Survival times were reduced in the TPN compared with the chow group, but IL-7 treatment significantly improved survival. Thus, exogenous IL-7 does not improve secretory IgA levels, nor are there any remarkable effects on levels of gut IgA-mediating cytokines. However, IL-7 treatment during TPN reverses TPN-induced GALT atrophy and improves survival in a gut-derived sepsis model.

Parenteral Feeding Depletes Pulmonary Lymphocyte Populations

BACKGROUND The effect of parenteral nutrition (PN) on lymphocyte mass in the lung is unknown, but reduced mucosal lymphocytes are hypothesized to play a role in the reduced immunoglobulin A-mediated immunity in both gut and lung. The ability to transfer and track cells between mice may allow study of diet-induced mucosal immune function. The objectives of this study are to characterize lung T-cell populations following parenteral feeding and to study distribution patterns of transferred donor lung T cells in recipient mice. METHODS In experiment 1, cannulated male Balb/c mice are randomized to receive chow or PN for 5 days. Lung lymphocytes are obtained via collagenase digestion, and flow cytometric analysis is used to identify total T (CD3+) and B (CD45/B220+) cells. In experiment 2, isolated lung T cells from chow-fed male Balb/c mice are pooled and labeled in vitro with a fluorescent dye (carboxyfluorescein diacetate succinimidyl ester [CFSE]), and 1.1 x 10(8) CFSE+ cells (3.1 x 10(6) T cells) are transferred to chow-fed Balb/c recipients. Cells recovered from recipient lungs and intestinal lamina propria (LP) are analyzed by flow cytometry to determine CFSE/CD3+ T cells at 1, 2, and 7 days. In experiment 3, cells are transferred to PN-fed recipients. RESULTS In experiment 1, PN significantly decreases lung T- and B-cell populations compared with chow feeding. In experiment 2, CFSE+ T-cell retention is highest on day 1 in lung and LP, and decreases on day 2. Cells are gone by day 7; 98.1% of retained donor lung T cells migrate to recipient lungs and 1.9% to the intestine on day 1. Similar results are seen in experiment 3 after transfer of cells to PN-fed recipients. CONCLUSIONS PN reduces pulmonary lymphocyte populations consistent with impaired respiratory immunity. Transferred lung T cells preferentially localize to recipient lungs rather than intestine with maximal accumulation at 24 hours. Limited cross-talk of transferred lung T cells to the intestine indicates that mucosal lymphocyte traffic might be programmed to localize to specific effector sites.

Nutritional route affects ERK phosphorylation and cytokine production in hepatic mononuclear cells.

Objective:To clarify the influence of nutritional route on hepatic immunity in a murine model. Summary Background Data:Parenteral nutrition is disadvantageous for preventing infectious complications in critically ill and/or severely injured patients as compared with enteral nutrition. To date, lack of enteral nutrition has been demonstrated to impair mucosal immunity, gut barrier function, and the peritoneal defense system. However, influences of nutritional route on hepatic immunity, another important defense system against infection, have not been well studied. Methods:Male ICR mice were randomized to 3 groups: ad libitum chow (chow), intravenous (IV)-TPN and intragastric (IG)-TPN groups. The TPN groups were given isocaloric and isonitrogenous TPN solutions. After the mice had been fed for 5 days, hepatic mononuclear cells (MNCs) were isolated. Hepatic MNC numbers and functions (cytokine production, intracellular signaling, and LPS receptor expression) were determined. Moreover, 1.0 × 107 Pseudomonas aeruginosa were delivered by intraportal injection. Survival and histology were examined. Results:Hepatic MNC numbers were significantly lower in the IV-TPN group than in the chow and IG-TPN groups, without subpopulation changes. As compared with enterally fed mice, cytokine production (TNF-α, IFN-γ, and IL-10) by hepatic MNCs in response to LPS was impaired in parenterally fed mice in association with blunted phosphorylation of ERK1/2, a MAPK. Hepatic MNCs from IV-TPN mice showed decreased expressions of CD14 and TLR4/MD2, as compared with enterally fed mice. Survival times were reduced in the IV-TPN group as compared with the chow and IG-TPN groups. Conclusion:Preservation of hepatic immunity with enteral feeding is important for prevention of infectious complications in severely injured and/or critically ill patients.

Parenteral Nutrition Inhibits Tumor Necrosis Factor-α-Mediated IgA Response to Injury

BACKGROUND Parenteral nutrition (PN) increases the incidence of pneumonia in severely injured patients compared with enteral feeding (ENT). Injury induces an innate airway IgA response in severely injured patients; similar responses occur in mice. Tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 beta (IL-1beta) stimulate the production of polymeric immunoglobulin receptor (pIgR), the protein required to transport immunoglobulin A (IgA) to mucosal surfaces. We have shown that PN alters levels of lung and nasal passage IgA and several IgA-stimulating cytokines. We hypothesized that TNF-alpha and IL-1beta blockade, as well as PN, would blunt the airway IgA response to injury. METHODS Male Institute of Cancer Research (ICR) mice were randomized to uninjured controls (n = 10) or to intra-peritoneal phosphate-buffered saline (PBS) (n = 9), antagonistic TNF-alpha antibody (100 mcg, n = 7), or antagonistic IL-1beta antibody (50 mcg, n = 8) 30 min prior to surgical stress with laparotomy and neck incisions. Mice were sacrificed at 8 h for nasal and bronchoalveolar lavage (NAL, BAL) to measure IgA by enzyme-linked immunosorbent assay. In a separate experiment, 12 mice underwent intravenous cannulation followed by chow (n = 5) or PN (n = 7) feeding for 5 days prior to the same stress and IgA measurement. RESULTS Injury significantly increased NAL and BAL IgA (225 +/- 104 ng) compared with baseline (145 +/- 38 ng; p = 0.01). Blockade of TNF-alpha eliminated the innate airway IgA response to injury (130 +/- 47 ng; p = 0.01), whereas IL-1beta blockade blunted and PN eliminated it completely. CONCLUSIONS Tumor necrosis factor-alpha is involved in the respiratory IgA immune response to injury. Both TNF-alpha blockade and PN impair this innate response, and blockade of IL-1beta impairs it to a degree. We hypothesize that these cytokines blunt this response via their known effects on the polymeric immunoglobulin receptor (pIgR), whereas the PN-induced deficit likely is multifactorial.

Reversal of parenteral nutrition-induced gut mucosal immunity impairment with small amounts of a complex enteral diet.

BACKGROUND Although parenteral nutrition (PN) prevents progressive malnutrition, lack of enteral nutrition (EN) during PN leads to gut associated lymphoid tissue (GALT) atrophy and dysfunction. Administering a small amount of EN with PN reportedly prevents increases in intestinal permeability. However, its effects on GALT remain unclear. We analyzed the minimum amount of EN required to preserve gut immunity during PN. METHODS Male Institute of Cancer Research mice underwent jugular vein catheter insertion and tube gastrostomy. They were randomized into four groups to receive isocaloric and isonitrogenous nutritional support with variable EN to PN ratios (EN 0, EN 33, EN 66, and EN 100). EN was provided with a complex enteral diet. After 5 days of feeding, the mice were killed and whole small intestines were harvested. GALT lymphocytes were isolated and counted. Their phenotypes were analyzed by flow cytometry. IgA levels of small intestinal washings were analyzed with enzyme-linked immunosorbent assay. RESULTS Body weight changes did not differ between any two of the groups. Peyers patch lymphocyte numbers increased in proportion to EN amount, whereas lamina propria lymphocyte numbers were significantly higher in the EN 100 than in the EN 0 group, with no marked increases in the EN 33 and EN 66 groups. Small intestinal IgA levels increased EN amount-dependently and reached a plateau at EN 66. CONCLUSIONS A small amount of EN partially reverses PN-induced GALT changes, suggesting beneficial but limited effects on gut mucosal immunity.

Decreased Enteral Stimulation Alters Mucosal Immune Chemokines

BACKGROUND Migration of lymphocytes into and through the mucosal immune system depends upon adhesion molecules to attract circulating cells and chemokines to stimulate diapedesis into tissues. Decreased enteral stimulation significantly reduces mucosal addressin cellular adhesion molecule-1 (MAdCAM-1) levels, an adhesion molecule critical for homing of T and B cells to Peyers patches (PP), which reduces PP and intestinal T and B cells. We studied the effect of type and route of nutrition on tissue specific chemokines in PP (CXCL-12, -13 and CCL-19, -20 and -21), small intestine (SI; CCL-20, -25 and -28) and lung (CXCL-12, CCL-28). METHODS Intravenously cannulated male Institute of Cancer Research (ICR) mice were randomized to chow or parenteral nutrition (PN) for 5 days. PP, SI, and lung chemokine mRNA levels were measured using real-time qRT-polymerase chain reaction, and analyzed semiquantitatively by the DeltaDeltaCt method. Protein levels were quantified using enzyme-linked immunosorbent assay (ELISA) techniques, and groups compared using Students t-test. RESULTS PP CXCL13 protein significantly decreased, whereas CCL21 protein increased significantly in the parenterally fed group. Parenteral feeding significantly decreased SI CCL20 and CCL 25 protein levels. CCL28 decreased significantly in the SI and lung of intravenously fed animals. mRNA levels changed in the opposite direction (compared with protein) for all chemokines except CCL28. CONCLUSIONS Decreased enteral stimulation significantly alters key mucosal immune chemokine protein levels at multiple sites. In general, PN (and concomitant lack of enteral stimulation) results in decreased levels of chemokines that control lymphocyte migration within the mucosal immune system.

Arginine-Enriched Total Parenteral Nutrition Improves Survival in Peritonitis by Normalizing NFκB Activation in Peritoneal Resident and Exudative Leukocytes

Background:Enteral nutrition maintains peritoneal defense more effectively than parenteral nutrition, at least partly by preserving NF&kgr;B activation in peritoneal cells. We hypothesized that arginine (ARG)-enriched parenteral nutrition would normalize NF&kgr;B activation in peritoneal leukocytes, thereby improving the survival of peritonitis models. Methods:A total of 105 ICR mice were randomized to chow (n = 33), IV feeding of a standard (STD) total parenteral nutrition (STD-TPN) solution (ARG 0.3%) (n = 35), or 1% ARG-TPN solution (n = 37), and fed accordingly for 5 days.Experiment 1: Thirty mice were used for intranuclear NF&kgr;B measurement in peritoneal resident cells (PRCs). After incubation with lipopolysaccharide (LPS: 0, 1, 10 &mgr;g/mL) for 30 minutes, intranuclear NF&kgr;B activity was examined by laser scanning cytometry.Experiment 2: Fifty-one mice were injected with 2 mL of 1% glycogen intraperitoneally. Peritoneal exudative cells (PECs) were obtained at 2 or 4 hours after glycogen administration for NF&kgr;B measurement. Cytokine (TNF&agr;, IL-10) levels in peritoneal lavage fluid were also determined by ELISA.Experiment 3: After 5 days of feeding, 24 mice underwent cecal ligation and puncture. Survival was observed up to 5 days. Results:Experiment 1: Intranuclear NF&kgr;B levels in the ARG-TPN and chow groups increased dose-dependently after LPS stimulation, while the level in the STD-TPN group was unchanged.Experiment 2: Intranuclear NF&kgr;B level was significantly higher at 2 hours in the chow than in the STD-TPN group, whereas in the ARG-TPN mice the level was midway between those of the chow and STD-TPN groups. TNF&agr; and IL-10 levels of the chow group were significantly higher than those of STD-TPN mice at 2 hours. TNF&agr; was significantly higher in the ARG-TPN group than in the STD-TPN group, but the IL-10 level showed no recovery.Experiment 3: Survival times were significantly reduced in the STD-TPN as compared with the chow group, though ARG-TPN improved survival. Conclusion:ARG-enriched TPN is a surrogate for enteral feeding which maintains peritoneal defense by preserving NF&kgr;B activation in peritoneal resident and exudative leukocytes.

Interleukin-7 Dose-Dependently Restores Parenteral Nutrition–Induced Gut-Associated Lymphoid Tissue Cell Loss but Does Not Improve Intestinal Immunoglobulin A Levels

BACKGROUND Without enteral nutrition, the mass and function of gut-associated lymphoid tissue (GALT), a center of systemic mucosal immunity, are reduced. Therefore, new therapeutic methods, designed to preserve mucosal immunity during parenteral nutrition (PN), are needed. Our recent study revealed that exogenous interleukin-7 (IL-7; 1 microg/kg twice a day) restores the GALT cell mass lost during intravenous (IV) PN but does not improve secretory immunoglobulin A (IgA) levels. Herein, we studied the IL-7 dose response to determine the optimal IL-7 dose for recovery of GALT mass and function during IV PN. We hypothesized that a high dose of IL-7 would increase intestinal IgA levels, as well as GALT cell numbers. METHODS Male mice (n = 42) were randomized to chow, IL-7-0, IL-7-0.1, IL-7-0.33, IL-7-1 and IL-7-3.3 groups and underwent jugular vein catheter insertion. The IL-7 groups were fed a standard PN solution and received IV injections of normal saline (IL-7-0), 0.1, 0.33, 1, or 3.3 microg/kg of IL-7 twice a day. The chow group was fed chow ad libitum. After 5 days of treatment, the entire small intestine was harvested and lymphocytes were isolated from Peyers patches (PPs), intraepithelial (IE) spaces, and the lamina propria (LP). The lymphocytes were counted and phenotypes determined by flow cytometry (alphabetaTCR, gammadeltaTCR, CD4, CD8, B cell). IgA levels of small intestinal washings were also examined using ELISA (enzyme-linked immunoabsorbent assay). RESULTS IL-7 dose-dependently increased total lymphocyte numbers in PPs and the LP. The number of lymphocytes harvested from IE spaces reached a plateau at 1 microg/kg of IL-7. There were no significant differences in any phenotype percentages at any GALT sites among the groups. IgA levels of intestinal washings were significantly higher in the chow group than in any of the IL-7 groups, with similar levels in all IL-7 groups. CONCLUSIONS Exogenous IL-7 dose-dependently reverses PN-induced GALT cell loss, with no major changes in small intestinal IgA levels. IL-7 treatment during PN appears to have beneficial effects on gut immunity, but other therapeutic methods are needed to restore secretory IgA levels.