Edward A. Carter

Mesenchymal Stem Cell-Derived Molecules Reverse Fulminant Hepatic Failure

Modulation of the immune system may be a viable alternative in the treatment of fulminant hepatic failure (FHF) and can potentially eliminate the need for donor hepatocytes for cellular therapies. Multipotent bone marrow-derived mesenchymal stem cells (MSCs) have been shown to inhibit the function of various immune cells by undefined paracrine mediators in vitro. Yet, the therapeutic potential of MSC-derived molecules has not been tested in immunological conditions in vivo. Herein, we report that the administration of MSC-derived molecules in two clinically relevant forms-intravenous bolus of conditioned medium (MSC-CM) or extracorporeal perfusion with a bioreactor containing MSCs (MSC-EB)-can provide a significant survival benefit in rats undergoing FHF. We observed a cell mass-dependent reduction in mortality that was abolished at high cell numbers indicating a therapeutic window. Histopathological analysis of liver tissue after MSC-CM treatment showed dramatic reduction of panlobular leukocytic infiltrates, hepatocellular death and bile duct duplication. Furthermore, we demonstrate using computed tomography of adoptively transferred leukocytes that MSC-CM functionally diverts immune cells from the injured organ indicating that altered leukocyte migration by MSC-CM therapy may account for the absence of immune cells in liver tissue. Preliminary analysis of the MSC secretome using a protein array screen revealed a large fraction of chemotactic cytokines, or chemokines. When MSC-CM was fractionated based on heparin binding affinity, a known ligand for all chemokines, only the heparin-bound eluent reversed FHF indicating that the active components of MSC-CM reside in this fraction. These data provide the first experimental evidence of the medicinal use of MSC-derived molecules in the treatment of an inflammatory condition and support the role of chemokines and altered leukocyte migration as a novel therapeutic modality for FHF.

Positron emission tomography (PET) imaging of neuroblastoma and melanoma with 64Cu-SarAr immunoconjugates

The advancement of positron emission tomography (PET) depends on the development of new radiotracers that will complement 18F-FDG. Copper-64 (64Cu) is a promising PET radionuclide, particularly for antibody-targeted imaging, but the high in vivo lability of conventional chelates has limited its clinical application. The objective of this work was to evaluate the novel chelating agent SarAr (1-N-(4-aminobenzyl)-3, 6,10,13,16,19-hexaazabicyclo[6.6.6] eicosane-1,8-diamine) for use in developing a new class of tumor-specific 64Cu radiopharmaceuticals for imaging neuroblastoma and melanoma. The anti-GD2 monoclonal antibody (mAb) 14.G2a, and its chimeric derivative, ch14.18, target disialogangliosides that are overexpressed on neuroblastoma and melanoma. Both mAbs were conjugated to SarAr using carbodiimide coupling. Radiolabeling with 64Cu resulted in >95% of the 64Cu being chelated by the immunoconjugate. Specific activities of at least 10 μCi/μg (1 Ci = 37 GBq) were routinely achieved, and no additional purification was required after 64Cu labeling. Solid-phase radioimmunoassays and intact cell-binding assays confirmed retention of bioactivity. Biodistribution studies in athymic nude mice bearing s.c. neuroblastoma (IMR-6, NMB-7) and melanoma (M21) xenografts showed that 15–20% of the injected dose per gram accumulated in the tumor at 24 hours after injection, and only 5–10% of the injected dose accumulated in the liver, a lower value than typically seen with other chelators. Uptake by a GD2-negative tumor xenograft was significantly lower (<5% injected dose per gram). MicroPET imaging confirmed significant uptake of the tracer in GD-2-positive tumors, with minimal uptake in GD-2-negative tumors and nontarget tissues such as liver. The 64Cu-SarAr-mAb system described here is potentially applicable to 64Cu-PET imaging with a broad range of antibody or peptide-based imaging agents.

Ethanol oxidation by liver microsomes: Evidence against a separate and distinct enzyme system

Abstract The TPNH dependent oxidation of ethanol by rat liver microsomes has been studied. Microsomes isolated by the usual centrifugation techniques contain TPNH oxidase, catalase and alcohol dehydrogenase (ADH). The latter two enzymes, known to be involved in ethanol metabolism, appear to be present largely as contaminants and their activity can be removed or decreased by washing. No evidence was obtained for the presence of a separate and distinct membrane bound ethanol oxidase. It is concluded that the TPNH and O 2 dependent metabolism of ethanol by microsomes can readily be explained by the coupled and combined activities of TPNH oxidase, catalase and ADH.

Prevention of necrotizing enterocolitis in the rat with prenatal cortisone

Cortisone acetate is known to accelerate maturation of the immature intestine. The effect of prenatal administration of cortisone acetate on the morbidity and mortality of necrotizing enterocolitis was examined in a rat pup model. Pregnant rats were administered cortisone acetate, 20 mg/100 g of body weight, or normal saline by daily IP injection from day 18-21 of gestation. Rat pups were taken from the mothers before suckling was initiated, fed a simulated rat milk formula, and subjected to daily ischemic insults to produce an animal model of necrotizing enterocolitis. Both morbidity and the mortality rates were significantly improved with prenatal cortisone treatment. Maturation of the intestinal mucosal barrier was accelerated with the cortisone treatment as measured by decreased serum concentrations of a fed antigen, ovalbumin. Aerobic bacterial colonization of the small intestine and translocation of bacteria to the liver were decreased in the pups pretreated with steroids. These changes observed in a rat model of necrotizing enterocolitis may explain the decreased incidence of necrotizing enterocolitis in human infants born to mothers who received corticosteroids late in gestation.

Ethanol inhibits hormone stimulated hepatocyte DNA synthesis

Insulin, glucagon, and epidermal growth factor (EGF) addition stimulated DNA synthesis in primary hepatocyte cell cultures prepared from adult rat liver. The addition of ethanol (20-200mM) to the culture medium resulted in a substantial reduction in DNA synthesis as measured by 3H-thymidine incorporation and autoradiography. This effect was specific for differentiated hepatocytes compared to fibroblasts and two other human hepatoma cell lines. These studies demonstrate in a cell culture system that one of the major properties of ethanol is the inhibition of hepatocyte DNA synthesis.

Lysyl Oxidase and Collagenase in Experimental Acute and Chronic Liver Injury

Lysyl oxidase and collagenase activities were measured in experimental acute and chronic liver injury in mice and rats, and correlated with collagen synthesis and accumulation. Acute liver injury was induced in mice and rats by a single dose of carbon tetrachloride given by gavage, and also in mice by a single injection of murine hepatitis virus. Chronic liver injury was induced in rats by repeated injections of carbon tetrachloride. Elevated plasma glutamic oxaloacetic transaminase levels, increased hepatic prolyl hydroxylase activity, and increased synthesis of collagen-bound hepatic hydroxyproline occurred in animals with acute as well as with chronic liver injury. However, only chronic liver injury appeared to be associated with fibrosis, increased collagen-bound hydroxyproline content, increased hepatic lysyl oxidase and collagenase activities, as well as with increased serum lysyl oxidase activity. These data suggest that lysyl oxidase and collagenase may play an important role in the collagen accumulation associated with hepatic fibrosis.

Ethanol Stimulates Triglyceride Synthesis by the Intestine

In vivo ethanol given acutely or chronically by two dietary means resulted in significant increases in [1-14C]palmitate incorporation into triglyceride by intestinal slices or microsomes derived from intestinal slices. In vitro, 2.6 percent ethanol, an amount comparable to that found in t..e intestinal lumen of social drinkers, also resulted in significant increases in [1-14C]palmitate incorporation into triglyceride. Pyrazole, an inhibitor of alcohol dehydrogenase, diminished the stimulatory effect of ethanol both in vivo and in vitro. These data may provide a new insight into the effects of alcohol, and specifically on the possible contribution of intestinal triglyceride synthesis to alcoholic hyperlipemia and the alcohol-induced fatty liver.

Metabolic alterations in muscle of thermally injured rabbits, measured by positron emission tomography

The hypermetabolic inflammatory state that occurs after major trauma has been extensively studied at the whole body level, however, there is only limited information on metabolic changes in individual tissues. In this study, the effect of thermal injury on metabolic function of uninjured hind limb muscle of rabbits was measured noninvasively by positron emission tomography (PET). Rabbits were subjected to full thickness burn on 25% of their body surface area. Two to three weeks after injury, PET and arterial blood sampling was performed during inhalation of 15O2, C15O2 and 11CO and after injection of 18FDG. The tissue and blood data were analyzed by standard kinetic models for blood flow, oxygen extraction fraction (OEF), oxygen utilization and glucose metabolism. A total of seven injured and five sham animals were studied. Total body oxygen consumption was measured by indirect calorimetry and plasma concentrations of glucose, insulin and IGF-1 were measured with standard assays. Compared to sham rabbits, blood flow to muscle of injured animals was unchanged. However, OEF, oxygen utilization and glucose metabolism were significantly reduced (p<0.01) in uninjured muscle of burned rabbits. These data demonstrate that thermal injury is associated with alterations in muscle metabolism, which are not related to change in blood flow.

Cytoskeletal Protein 4.1R Affects Repolarization and Regulates Calcium Handling in the Heart

The 4.1 proteins are a family of multifunctional adaptor proteins. They promote the mechanical stability of plasma membranes by interaction with the cytoskeletal proteins spectrin and actin and are required for the cell surface expression of a number of transmembrane proteins. Protein 4.1R is expressed in heart and upregulated in deteriorating human heart failure, but its functional role in myocardium is unknown. To investigate the role of protein 4.1R on myocardial contractility and electrophysiology, we studied 4.1R-deficient (knockout) mice (4.1R KO). ECG analysis revealed reduced heart rate with prolonged Q-T interval in 4.1R KO. No changes in ejection fraction and fractional shortening, assessed by echocardiography, were found. The action potential duration in isolated ventricular myocytes was prolonged in 4.1R KO. Ca2+ transients were larger and slower to decay in 4.1R KO. The sarcoplasmic reticulum Ca2+ content and Ca2+ sparks frequency were increased. The Na+/Ca2+ exchanger current density was reduced in 4.1R KO. The transient inward current inactivation was faster and the persistent Na+ current density was increased in the 4.1R KO group, with possible effects on action potential duration. Although no major morphological changes were noted, 4.1R KO hearts showed reduced expression of NaV1.5&agr; and increased expression of protein 4.1G. Our data indicate an unexpected and novel role for the cytoskeletal protein 4.1R in modulating the functional properties of several cardiac ion transporters with consequences on cardiac electrophysiology and with possible significant roles during normal cardiac function and disease.

Thermal injury and gastrointestinal function. I. Small intestinal nutrient absorption and DNA synthesis.

The effect of acute burn trauma, produced by scalding hot water, on rat small intestinal nutrient absorption and DNA synthesis has been examined. Burned rats showed decreased small-intestine mucosal weight and altered small-intestine transport of nutrients (calcium, glucose, or amino acid) in vitro. In addition, there was decreased 3H-thymidine incorporation into intestinal DNA in vivo and decreased intestinal thymidine kinase activity in vitro 18 hours after acute burn. These data suggest that after the severe stress produced by acute burn trauma, there is altered small-intestine nutrient absorption and DNA synthesis. These alterations may affect delivery of nutrients by the gut to the burn patient.