Pancreaticoduodenectomy for lymphoepithelial cyst of the pancreas.

Lymphoepithelial tumors of the pancreas are rare cystic tumors characterized by the presence of a keratinizing squamous epithelium and a dense lymphoid infiltrate on histologic examination. This case report describes the first lymphoepithelial tumor to be resected from the pancreatic head by pancreaticoduodenectomy. This case is also the first in which the cyst was found to be secondarily infected. The radiologic and clinicopathologic features of these unusual tumors are discussed.

Time course and cellular localization of inducible nitric oxide synthases expression during cardiac allograft rejection.

BACKGROUND: We have demonstrated that inhibition of inducible nitric oxide synthase (NOS) ameliorated acute cardiac allograft rejection. This study determined the time course and cellular localization of inducible NOS expression during the histologic progression of unmodified acute rat cardiac allograft rejection. METHODS: Tissue from syngeneic (ACI to ACI) and allogeneic (Lewis to ACI) transplants were harvested on postoperative days 3 through 10 and analyzed for inducible NOS mRNA expression (ribonuclease protection assay), inducible NOS enzyme activity (conversion of L-[3H]arginine to nitric oxide and L-[3H]citrulline), and nitric oxide production (serum nitrite/nitrate levels). Inducible NOS mRNA and protein expression were localized using in situ hybridization and immunohistochemistry. RESULTS: Inducible NOS mRNA and enzyme activity were expressed in allografts during mild, moderate, and severe acute rejection (postoperative days 4 through 10), but were not detected in normals, isografts, or allografts before histologic changes of mild acute rejection (postoperative day 3). Inducible NOS expression resulted in increased serum nitrite/nitrate levels during mild and moderate rejection (postoperative days 4 through 6). Inducible NOS mRNA and protein expression localized to infiltrating mononuclear inflammatory cells in allograft tissue sections during all stages of rejection but were not detected in allograft parenchymal cells or in normals or isografts. CONCLUSIONS: Inducible NOS expression and increased nitric oxide production occurred during the early stages of acute rejection, persisted throughout the unmodified rejection process, and localized to infiltrating inflammatory cells but not allograft parenchymal cells during all stages of acute rejection.

Inflammatory cell-derived NO modulates cardiac allograft contractile and electrophysiological function.

We previously demonstrated that inhibition of inducible nitric oxide (NO) synthase (iNOS) ameliorated acute cardiac allograft rejection. This study used a rat cardiac transplant model to characterize contractile and electrophysiological dysfunction during early acute rejection, further examine the role of NO and iNOS in this process, and determine which cells expressed iNOS during early rejection. During early acute rejection, before significant myocyte necrosis, allograft papillary muscles had reduced tension development and rates of tension development and decline during beta-adrenergic, adenylate cyclase, and calcium stimulation compared with isograft and normals [e.g., tension of 36 (allograft) vs. 73 (isograft) mN/mm2 during calcium stimulation, P < 0.001]. Allografts had resting membrane potential depolarization and reduced action potential amplitude and upstroke velocity. iNOS mRNA was expressed in infiltrating inflammatory cells but not in allograft myocytes, endothelial cells, or isografts. Corticosteroids attenuated allograft contractile and electrophysiological dysfunction and inhibited iNOS enzyme activity. Direct iNOS inhibition with aminoguanidine inhibited NO production and prevented allograft contractile and electrophysiological dysfunction (e.g., tension of 64 mN/mm2 during calcium stimulation, P < 0.001). We conclude that 1) early allograft rejection caused contractile and electrophysiological dysfunction that was largely mediated by iNOS expression in infiltrating inflammatory cells, 2) corticosteroid-mediated amelioration of allograft contractile and electrophysiological dysfunction may reflect inhibition of iNOS, and 3) iNOS inhibition may offer an alternative in management of immune-mediated myocardial dysfunction.

Inhibition of inducible nitric oxide synthase ameliorates functional and histological changes of acute lung allograft rejection.

BACKGROUND: We recently demonstrated that inhibition of inducible nitric oxide synthase (iNOS) ameliorated severe acute lung allograft rejection. This study used a rat lung transplant model to determine (1) the time course and cellular localization of iNOS expression during the histological progression of unmodified acute rejection and (2) whether inhibition of iNOS prevented impaired gas exchange function of the allograft lung and/or ameliorated the histological changes of acute rejection. METHODS AND RESULTS: iNOS mRNA and enzyme activity were expressed in allograft lungs during mild, moderate, and severe acute rejection, but not in normal, isograft, or allograft lungs before histological changes of mild acute rejection. iNOS expression in allografts resulted in elevated serum nitrite/nitrate levels, indicative of increased in vivo nitric oxide (NO) production. In situ hybridization demonstrated iNOS mRNA expression in infiltrating inflammatory cells, but not in allograft parenchymal cells. Allografts had significantly impaired gas exchange, which was prevented with the selective iNOS inhibitor aminoguanidine (PaO2 of 566+/-19, 76+/-22, and 504+/-105 mmHg for isograft, allograft, and aminoguanidine-treated allograft, respectively; P<0.0002). Aminoguanidine also significantly improved the histological rejection scores. CONCLUSIONS: (1) iNOS expression and increased NO production occurred during the early stages of acute rejection, persisted throughout the unmodified rejection process, and localized to infiltrating inflammatory cells, but not allograft parenchymal cells; (2) aminoguanidine ameliorated the histological and functional changes of acute rejection; and (3) increased NO production, detected by the presence of iNOS mRNA, protein, or noninvasively by measuring serum nitrite/nitrate levels, may serve as an early marker of acute allograft rejection.

Inducible nitric oxide synthase is expressed during experimental acute lung allograft rejection.

BACKGROUND: We recently demonstrated that inhibition of nitric oxide (NO) production ameliorated acute pulmonary allograft rejection. This study examined whether inducible NO synthase (iNOS) was expressed in the transplanted lung during acute rejection. METHODS: With a rat left lung transplant model, tissue from syngeneic (Fischer 344 to Fischer 344) and allogeneic (Brown Norway to Fischer 344) transplants were harvested on postoperative day 4 and analyzed for iNOS mRNA expression (ribonuclease protection assay), iNOS enzyme activity (conversion of L-[3H]-arginine to NO and L-[3H]-citrulline), and serum nitrite/nitrate levels. RESULTS: The iNOS mRNA was expressed in allograft lungs but was not detected in isografts or controls. The iNOS protein was present in allograft lungs, as demonstrated by high levels of L-[3H]-citrulline production compared with minimal iNOS enzyme activity in isograft and control lungs (10.1 +/- 2.4 vs 0.6 +/- 0.2 and 0.7 +/- 0.2 pmol L-[3H]-citrulline.mg-1.min-1, respectively; n = 6, p < 0.001). Allografts had significantly elevated systemic serum nitrite/nitrate levels compared with isografts and controls (38 +/- 6 vs 18 +/- 2 and 16 +/- 1 mumol/L, respectively; n = 6; p < 0.005). CONCLUSIONS: These results, together with our previous demonstration that iNOS inhibition ameliorated lung allograft rejection, suggest that (1) iNOS expression and increased NO production contributed to acute rejection of the transplanted lung, (2) iNOS inhibition may offer an alternative in management of acute lung allograft rejection, and (3) increased NO production, detected by the presence of iNOS mRNA or protein or noninvasively by measuring serum nitrite/nitrate levels, may serve as an early marker of acute allograft rejection.

TNF-alpha causes reversible in vivo systemic vascular barrier dysfunction via NO-dependent and -independent mechanisms.

Tumor necrosis factor (TNF-alpha) and nitric oxide (NO) are important vasoactive mediators of septic shock. This study used a well-characterized quantitative permeation method to examine the effect of TNF-alpha and NO on systemic vascular barrier function in vivo, without confounding endotoxemia, hypotension, or organ damage. Our results showed 1) TNF-alpha reversibly increased albumin permeation in the systemic vasculature (e.g., lung, liver, brain, etc.); 2) TNF-alpha did not affect hemodynamics or blood flow or cause significant tissue injury; 3) pulmonary vascular barrier dysfunction was associated with increased lung water content and impaired oxygenation; 4) TNF-alpha caused inducible nitric oxide synthase (iNOS) mRNA expression in the lung and increased in vivo NO production; 5) selective inhibition of iNOS with aminoguanidine prevented TNF-alpha-induced lung and liver vascular barrier dysfunction; 6) aminoguanidine prevented increased tissue water content in TNF-alpha-treated lungs and improved oxygenation; and 7) nonselective inhibition of NOS with NG-monomethly-L-arginine increased vascular permeation in control lungs and caused severe lung injury in TNF-alpha-treated animals. We conclude that 1) TNF-alpha reversibly impairs vascular barrier integrity through NO-dependent and -independent mechanisms; 2) nonselective NOS inhibition increased vascular barrier dysfunction and caused severe lung injury, whereas selective inhibition of iNOS prevented impaired endothelial barrier integrity and pulmonary dysfunction; and 3) selective inhibition of iNOS may be beneficial in treating increased vascular permeability that complicates endotoxemia and cytokine immunotherapy.

Inhibition of inducible nitric oxide synthase attenuates established acute cardiac allograft rejection.

BACKGROUND: We previously demonstrated that continuous treatment with aminoguanidine, a selective inhibitor of nitric oxide production by inducible nitric oxide synthase, attenuated acute cardiac allograft rejection. METHODS: A rat transplant model was used to determine (1) when inducible nitric oxide synthase was expressed in the allograft heart during unmodified acute rejection and (2) whether pulse therapy with aminoguanidine attenuated the histologic changes of established acute rejection, in comparison with the effects of pulse therapy with corticosteroids. RESULTS: Inducible nitric oxide synthase messenger RNA and protein were expressed during early and late acute rejection. Pulse therapy with aminoguanidine inhibited nitric oxide production and attenuated the histologic changes of acute rejection, but not as effectively as corticosteroid therapy (rejection scores of 4.1 +/- 0.4, 2.5 +/- 0.9, and 1.4 +/- 0.6 on postoperative day 8, for untreated, aminoguanidine-, and dexamethasone-treated allografts, respectively (scale, 0 to 5; p < 0.05). CONCLUSIONS: (1) Inducible nitric oxide synthase expression first occurs during early acute allograft rejection and persists throughout rejection and (2) nitric oxide is an important effector molecule in acute rejection. Inducible nitric oxide synthase inhibition may offer a therapeutic adjunct in the management of acute rejection.

Inhibition of inducible nitric oxide synthase prevents myocardial and systemic vascular barrier dysfunction during early cardiac allograft rejection.

NO is produced during cardiac allograft rejection by expression of inducible NO synthase (iNOS) in the rejecting heart. Recent evidence indicates that NO modulates vascular permeability under both physiological and pathophysiological conditions. The present study explored the effects of early acute cardiac allograft rejection, and specifically the effects of NO, on myocardial and systemic vascular barrier function using a quantitative double-tracer permeation method in a rat cardiac transplant model. Early allograft rejection increased albumin permeation twofold to fivefold in the allograft heart and systemic vasculature (brain, lung, sciatic nerve, diaphragm, retina, muscle, kidney, and uvea) compared with isografts and controls. There were no detectable differences in regional blood flow or hemodynamics, suggesting that increased albumin permeation resulted from increased vascular permeability. iNOS mRNA was expressed in the allograft heart and native lung and was associated with increased serum nitrite/nitrate levels. iNOS inhibition with aminoguanidine prevented or attenuated allograft heart and systemic vascular barrier dysfunction and reduced allograft serum nitrite/nitrate levels to isograft values. Aminoguanidine did not affect the mild histological changes of rejection present in allografts. These data demonstrate the novel observations that (1) endothelial barrier function is compromised in the systemic vasculature, particularly in the brain, remote from the site of allograft rejection; (2) allograft vascular barrier dysfunction is associated with increased NO production and iNOS mRNA expression in the affected tissues (eg, native lung and grafted heart); and (3) inhibition of NO production by iNOS prevents vascular barrier dysfunction in the allograft heart and systemic vasculature.

Corticosteroids inhibit expression of inducible nitric oxide synthase during acute cardiac allograft rejection.

We have recently demonstrated that (1) nitric oxide (NO) is produced during experimental cardiac allograft rejection by the expression of inducible nitric oxide synthase (iNOS) in the rejecting organ and that (2) inhibition of NO production by iNOS attenuated acute rejection. The present study examined the interaction of corticosteroids, iNOS gene expression, and iNOS enzyme activity in a rat cardiac transplant model. Increased NO production in rejecting allografts was demonstrated by elevated serum nitrite/nitrate levels (67 +/- 5 versus 18 +/- 2 microM for isografts; P < 0.001) that were significantly reduced by pulse therapy with dexamethasone for 2 days prior to animal sacrifice or continuous dexamethasone treatment (34 +/- 2 and 19 +/- 4 microM, respectively; P < 0.001 versus untreated allografts). Increased iNOS enzyme activity was demonstrated in the allograft heart (5.11 +/- 1.00 versus 0.3 +/- 0.05 pmol L-citrulline.mg protein-1.min-1 for isografts) and was significantly reduced with dexamethasone treatment (1.13 +/- 0.47 for 2-day pulse-treated allografts and 0.02 +/- 0.01 for continuously treated allografts). Increased allograft iNOS enzyme activity resulted from induction of iNOS mRNA expression, which was more than 99% inhibited by dexamethasone treatment. Dexamethasone pulse therapy reduced but did not eliminate the histological changes of acute rejection. Thus corticosteroid treatment results in inhibition of iNOS expression during allograft rejection. These results further demonstrate that iNOS expression during acute rejection is immune-mediated and suggest that the immunosuppressive actions of corticosteroids in the treatment of acute rejection may include inhibition of iNOS expression.

Inhibition of inducible nitric oxide synthase ameliorates rat lung allograft rejection.

Recently, the inducible isoform of nitric oxide synthase has been shown to be an important immunomodulation molecule in allograft rejection. We have observed the production of nitric oxide during rejection and the effect of nitric oxide synthase inhibition on allograft rejection in a rat lung transplant model. Rat left lung allotransplants were performed in two strain combinations: brown Norway-to-F344 (major histocompatibility complex incompatible); and Lewis-to-F344 (minor loci incompatible) as severe and mild rejection models respectively. Syngeneic F344-to-F344 transplants were performed as a negative control. Nitric oxide production during rejection was determined by measuring the recipient's serum nitrite/nitrate levels as a stable end product of nitric oxide. The progression of rejection was evaluated radiographically and the grade of rejection was determined histologically. After operation, recipients of allotransplantation were randomly divided into two groups and received either aminoguanidine (200 mg/kg, intraperitoneal every 6 hours), a potent inducible nitric oxide synthase inhibitor, or normal saline treatment. The levels of serum nitrite and nitrate in recipients increased in the early phase of rejection in both allotransplant combinations. However, in the terminal phase of rejection, the serum nitrite/nitrate level decreased significantly compared with the peak level in the brown Norway-to-F344 recipients. The serum nitrite/nitrate levels in the syngeneic transplant recipients were normal during the entire observation period. In aminoguanidine-treated animals, serum nitrite/nitrate levels remained normal in both allograft combinations. Significant suppression of rejection in aminoguanidine-treated recipients was observed histologically and radiographically in comparison with untreated recipients in the brown Norway-to-F344 combinations. In the Lewis-to-F344 combination, aminoguanidine treatment significantly ameliorated histologic rejection but did not affect radiologic appearance. We therefore conclude nitric oxide is produced during early allograft rejection and may prove to be a marker and mediator of early rejection. The inhibition of inducible nitric oxide synthase results in significant reduction in rat lung allograft rejection.

Modulation of in vivo alloreactivity by inhibition of inducible nitric oxide synthase.

The role of nitric oxide in the immune response to allogeneic tissue was explored in an in vivo cardiac transplant model in the rat. Nitric oxide production during organ rejection was demonstrated by elevations in systemic serum nitrite/nitrate levels and by electron paramagnetic resonance spectroscopy. Messenger RNA for the inducible nitric oxide synthase enzyme was detected in the rejecting allografted heart, but not in the nonrejecting isografted heart. The enzyme was demonstrated to be biologically active by the in vitro conversion of L-arginine to L-citrulline and was immunohistochemically localized to the infiltrating inflammatory cells. Treatment with aminoguanidine, a preferential inhibitor of the inducible nitric oxide synthase isoform, prevented the increased nitric oxide production in the transplanted organ and significantly attenuated the pathogenesis of acute rejection. Aminoguanidine treatment prolonged graft survival, improved graft contractile function, and significantly reduced the histologic grade of rejection. These results suggest an important role for nitric oxide in mediating the immune response to allogeneic tissue. Inhibition of inducible nitric oxide synthase may provide a novel therapeutic modality in the management of acute transplant rejection and of other immune-mediated processes.

Expression of von Willebrand factor "Normandy": an autosomal mutation that mimics hemophilia A.

von Willebrand disease Normandy (vWD Normandy) is a recently described phenotype in which a mutant von Willebrand factor (vWF) appears structurally and functionally normal except that it does not bind to blood coagulation factor VIII. This interaction is required for normal survival of factor VIII in the circulation; consequently, vWD Normandy can present as apparent hemophilia A but with autosomal recessive rather than X chromosome-linked inheritance. A vWF missense mutation, Thr28----Met, was identified in the propositus in or near the factor VIII binding site. The corresponding mutant recombinant vWF(T28M) formed normal multimers and had normal ristocetin cofactor activity. However, vWF(T28M) exhibited the same defect in factor VIII binding as natural vWF Normandy, confirming that this mutation causes the vWD Normandy phenotype. The distinction between hemophilia A and vWD Normandy is clinically important and should be considered in families affected by apparent mild hemophilia A that fail to show strict X chromosome-linked inheritance and, particularly, in potential female carriers with low factor VIII levels attributed to extreme lyonization.

Structure of the gene for human von Willebrand factor.

von Willebrand factor is a large multimeric plasma protein composed of identical subunits which contain four types of repeated domains. von Willebrand factor is essential for normal hemostasis, and deficiency of von Willebrand factor is the most common inherited bleeding disorder of man. Four human genomic DNA cosmid libraries and one bacteriophage lambda library were screened with von Willebrand factor cDNA probes. Twenty positive overlapping clones were characterized that span the entire von Willebrand factor gene. A high-resolution restriction map was constructed for approximately 75% of the locus and a total of approximately 33.8 kilobases was sequenced on both strands including all intron-exon boundaries. The gene is approximately 178 kilobases in length and contains 52 exons. The exons vary from 40 to 1379 base pairs in length, and the introns vary from 97 base pairs to approximately 19.9 kilobases in length. The signal peptide and propeptide (von Willebrand antigen II) of von Willebrand factor are encoded by 17 exons in approximately 80 kilobases of DNA while the mature subunit of von Willebrand factor and 3' noncoding region are encoded by 35 exons in the remaining approximately 100 kilobases of the gene. A number of repetitive sequences were identified including 14 Alu repeats and a approximately 670-base pair TCTA simple repeat in intron 40 that is polymorphic. Regions of the gene that encode homologous domains have similar structures, supporting a model for their origin by gene segment duplication.