D L Granger

Specific amino acid (L-arginine) requirement for the microbiostatic activity of murine macrophages.

The microbiostatic action of macrophages was studied in vitro employing peritoneal cytotoxic macrophages (CM) from mice acting against Cryptococcus neoformans cultured in Dulbeccos medium with 10% dialyzed fetal bovine serum. Fungistasis was measured using electronic particle counting after lysis of macrophages with detergent. Macrophage fungistasis failed in medium lacking only L-arginine. Complete fungistasis was restored by L-arginine; restoration was concentration dependent, maximal at 200 microM. Deletion of all other essential amino acids did not abrogate fungistasis provided that L-arginine was present. Of twenty guanido compounds, including D-arginine, only three (L-arginine, L-homoarginine, and L-arginine methylester) supported fungistasis. Known activators or mediators of macrophage cytotoxicity (endotoxin, interferon gamma, tumor necrosis factor) did not replace L-arginine for CM-mediated fungistasis. The guanido analogue NG-monomethyl-L-arginine was a potent competitive inhibitor of CM-mediated fungistasis giving 50% inhibition at an inhibitor/L-arginine ratio of 1:27. Although CM completely blocked fungal reproduction via an L-arginine-dependent mechanism, the majority of the dormant fungi remained viable. Thus, this mechanism is viewed as a microbiostatic process similar or identical to the tumoristatic effect of macrophages. This suggests the production of a broad spectrum biostatic metabolite(s) upon consumption of L-arginine by cytotoxic macrophages.

Virulence of Cryptococcus neoformans. Regulation of capsule synthesis by carbon dioxide.

Cryptococcus neoformans is variably encapsulated in vitro, whereas in tissues it develops a large capsule. We observed that cells of a strain with thin capsules, when growing in a standard fungal culture medium, became heavily encapsulated when incubated in serum-free cell culture medium (Dulbeccos modified Eagles medium [DME]). Capsule size was quantitated physically by measuring cell volume, and chemically by determining the content of a capsular monosaccharide, glucuronate. The CO2/HCO-3 couple stimulated capsule development, resulting in visible enlargement by 3 h after exposure to high CO2/HCO-3. The amount of capsule per cell was directly proportional to the total millimolar CO2/HCO-3 concentration between 24 and 2.4 mM at pH 7.35, but at constant PCO2 (40 torr) and varying [HCO-3], the cells were heavily encapsulated down to pH 6.8. Concentration of CO2/HCO-3 in the physiologic range increased elaboration of polysaccharide into the medium and slowed the cell generation time from 2 to 6 h. Four other first-passage clinical isolates were all heavily encapsulated in DME with CO2/HCO-3, but variably encapsulated in DME without CO2/HCO-3. Exposure of yeast to increased CO2/HCO-3 caused a marked reduction in complement-mediated phagocytosis by mouse macrophages. A stable clone was isolated which contained capsular polysaccharide, but lacked the CO2-inducible phenotype. This clone was avirulent for steroid-treated rabbits. Thus, the prevailing CO2 concentration in mammalian tissues may be one stimulus for capsular polysaccharide synthesis. This could serve as an adaptive mechanism favoring parasite survival in the host.

A promoter polymorphism in the gene encoding interleukin-12 p40 (IL12B) is associated with mortality from cerebral malaria and with reduced nitric oxide production.

Interleukin-12 (IL-12) is an important regulatory cytokine in infection and immunity. Administration of IL-12 may reduce complications of severe malaria in rodents. Polymorphisms in IL12B, the gene encoding the IL-12 p40 subunit, influence the secretion of IL-12 and susceptibility to Type 1 diabetes. We therefore investigated whether IL12B polymorphisms may affect the outcome of severe malaria. Homozygosity for a polymorphism in the IL12B promoter was associated with increased mortality in Tanzanian children having cerebral malaria but not in Kenyan children with severe malaria. Furthermore, homozygotes for the IL12B promotor polymorphism had decreased production of nitric oxide, which is in part regulated by IL-12 activity. These studies suggest that IL12B polymorphisms, via regulation of IL-12 production, may influence the outcome of malaria infection in at least one African population.

Nω-monomethyl-l-arginine inhibits nitric oxide production in murine cardiac allografts but does not affect graft rejection

Endogenous nitric oxide biosynthesis in mice receiving allogeneic heterotopic heart transplants was monitored as a function of time post-transplant. Nitric oxide production was measured by daily urine nitrate levels and by formation of paramagnetic heme-nitrosyl complexes in the cardiac tissue. Exogenous sources of urine nitrate and EPR signal were minimized by maintaining the animals on a low nitrite/nitrate diet. Urine nitrate peaked on postoperative day 7. A heme-nitrosyl EPR signal also appeared in the cardiac tissue on postoperative day 7 and remained unchanged in size until rejection on postoperative day 9 at which time the peak height of the signal nearly tripled. Some of the animals in the study were treated with the nitric oxide synthase inhibitor, N omega-monomethyl-L-arginine which caused marked inhibition of urinary nitrate excretion and prevented heme-nitrosyl complex formation in beating hearts. However, administration of the inhibitor did not increase graft survival time. Low intensity heme-nitrosyl signals were identified in inhibitor-treated allogeneic hearts after rejection. Syngeneic heart transplants did not induce urinary nitrate excretion nor EPR signal formation. These results show that cytokine induced high output nitric oxide synthesis from L-arginine is a prominent biochemical component of the cell-mediated immune response to cardiac allografts in mice. However, nitric oxide production was not essential for rejection of cardiac allografts mismatched at the major histocompatibility locus.

Aberrant Oxygen Metabolism in Neoplastic Cells Injured by Cytotoxic Macrophages

The focus of this workshop is to explore the mechanisms by which leukocytes injure other cells. Macrophages are particularly unique cells to study for two reason. First, cytotoxicity may not always be manifested as a lytic event. The early work of Evans and Alexander clearly demonstrated the profound and long-term antimitotic effect macrophages exert on neoplastic targets (1). When death does occur it may be many hours following the arrest of cell division. In no other effector-target cell interaction is the complete cessation of reproduction so dissociable from cell death and such a paramount feature of cell injury. Secondly, the efficiency and spectrum of macrophage-mediated cytostasis is remarkable. Under appropriate in vitro conditions virtually all added cells of a given target cell line are prevented from dividing. Furthermore, of the numerous neoplastic cell types which have been studied, none are capable of dividing in the presence of macrophages which have differentiated to the cytotoxic state (2). Our contribution to this conference deals with macrophage cytostasis. We have studied metabolic changes which occur in neoplastic cells upon contact with mouse peritoneal cytotoxic macrophages (CM) invitro. These studies followed an observation that macrophage-injured neoplastic cells developed an unusual carbohydrate dependence. It is possible that understanding changes which occur in target cells upon CM-induced injury may provide insight into defining the biochemical mechanisi (s) by which CM exert their universal antimitotic action.