An update on sargramostim for treatment of acute radiation syndrome

The potential use by terrorists of an improvised nuclear device, a radiological dispersal device, or an unintended nuclear/radiological accident in heavily populated areas is a national security threat of major consequences. Although this type of security threat is considered to be low-risk, it would have a devastating impact. Health issues would be a major concern; medical care would be necessary for all those who received considerable radiation exposure (> 1 Gy) leading to hematopoietic acute radiation syndrome (ARS). In the past few years, the U.S. Food and Drug Administration (FDA) has approved for such radiation exposure contingencies recombinant human granulocyte colony-stimulating factor (rhG-CSF, filgrastim, Neupogen), PEGylated rhG-CSF (PEGylated filgrastim, Neulasta) and granulocyte-macrophage colony-stimulating factor (rhGM-CSF, sargramostim, Leukine) following the FDA's Animal Rule guidance. In this article, we have briefly reviewed the consequences of exposure to acute, potentially lethal doses of radiation and its pathologic sequelae, as well as ARS and the latest of the FDA-approved recombinant growth factors, namely sargramostim (Leukine), as a new treatment option for the subclinical, hematopoietic syndrome component of ARS. The nature of the recombinant and the preclinical and clinical research that preceded approval by the FDA are presented, as well as its use in the treatment of victims of radiation accidents.

ICRP Publication 131: Stem Cell Biology with Respect to Carcinogenesis Aspects of Radiological Protection

This report provides a review of stem cells/progenitor cells and their responses to ionising radiation in relation to issues relevant to stochastic effects of radiation that form a major part of the International Commission on Radiological Protection's system of radiological protection. Current information on stem cell characteristics, maintenance and renewal, evolution with age, location in stem cell 'niches', and radiosensitivity to acute and protracted exposures is presented in a series of substantial reviews as annexes concerning haematopoietic tissue, mammary gland, thyroid, digestive tract, lung, skin, and bone. This foundation of knowledge of stem cells is used in the main text of the report to provide a biological insight into issues such as the linear-no-threshold (LNT) model, cancer risk among tissues, dose-rate effects, and changes in the risk of radiation carcinogenesis by age at exposure and attained age. Knowledge of the biology and associated radiation biology of stem cells and progenitor cells is more developed in tissues that renew fairly rapidly, such as haematopoietic tissue, intestinal mucosa, and epidermis, although all the tissues considered here possess stem cell populations. Important features of stem cell maintenance, renewal, and response are the microenvironmental signals operating in the niche residence, for which a well-defined spatial location has been identified in some tissues. The identity of the target cell for carcinogenesis continues to point to the more primitive stem cell population that is mostly quiescent, and hence able to accumulate the protracted sequence of mutations necessary to result in malignancy. In addition, there is some potential for daughter progenitor cells to be target cells in particular cases, such as in haematopoietic tissue and in skin. Several biological processes could contribute to protecting stem cells from mutation accumulation: (a) accurate DNA repair; (b) rapidly induced death of injured stem cells; (c) retention of the DNA parental template strand during divisions in some tissue systems, so that mutations are passed to the daughter differentiating cells and not retained in the parental cell; and (d) stem cell competition, whereby undamaged stem cells outcompete damaged stem cells for residence in the niche. DNA repair mainly occurs within a few days of irradiation, while stem cell competition requires weeks or many months depending on the tissue type. The aforementioned processes may contribute to the differences in carcinogenic radiation risk values between tissues, and may help to explain why a rapidly replicating tissue such as small intestine is less prone to such risk. The processes also provide a mechanistic insight relevant to the LNT model, and the relative and absolute risk models. The radiobiological knowledge also provides a scientific insight into discussions of the dose and dose-rate effectiveness factor currently used in radiological protection guidelines. In addition, the biological information contributes potential reasons for the age-dependent sensitivity to radiation carcinogenesis, including the effects of in-utero exposure.

ICRP Publication 131: Stem cell biology with respect to carcinogenesis aspects of radiological protection

Current knowledge of stem cell characteristics, maintenance and renewal, evolution with age, location in 'niches', and radiosensitivity to acute and protracted exposures is reviewed regarding haematopoietic tissue, mammary gland, thyroid, digestive tract, lung, skin, and bone. The identity of the target cells for carcinogenesis continues to point to the more primitive and mostly quiescent stem cell population (able to accumulate the protracted sequence of mutations necessary to result in malignancy), and, in a few tissues, to daughter progenitor cells. Several biological processes could contribute to the protection of stem cells from mutation accumulation: (1) accurate DNA repair; (2) rapid induced death of injured stem cells; (3) retention of the intact parental strand during divisions in some tissues so that mutations are passed to the daughter differentiating cells; and (4) stem cell competition, whereby undamaged stem cells outcompete damaged stem cells for residence in the vital niche. DNA repair mainly operates within a few days of irradiation, while stem cell replications and competition require weeks or many months depending on the tissue type. This foundation is used to provide a biological insight to protection issues including the linear-non-threshold and relative risk models, differences in cancer risk between tissues, dose-rate effects, and changes in the risk of radiation carcinogenesis by age at exposure and attained age.

N‐Palmitoylation of the Radioprotective Domain of Interleukin‐1 Affords Inhibition of LPS‐Induced Nitric Oxide Generation

Interleukin-1beta (IL-1beta), a cytokine involved in homeostatic processes such as the immune system and inflammatory reactions, is a potent inducer of nitric oxide. The nonapeptide of human IL-1beta (VQGEESNDK, position 163-171, specific radioprotective domain--SRD) has been shown to retain radioprotective, immunostimulatory, and adjuvant activities of the native molecule without any inflammatory and pyrogenic properties. Unlike the parent IL-1, SRD did not induce nitric oxide (NO) in control or irradiated RAW 264.7 cells nor did it affect inducible nitric oxide synthase (iNOS) as shown by ELISA based mRNA assay (Quantikine). A lipophillic derivative of the SRD (a palmitoyl residue at the amino terminus of the SRD) was synthesized (palmitoyl specific radioprotective domain, P-SRD) to find out if this structural derivatization would restore the NO-inducing ability of IL-1. Surprisingly, P-SRD not only did not induce NO, but significantly inhibited lipopolysaccharide (LPS) stimulated nitric oxide (NO) production. Quantikine studies indicated that P-SRD also inhibited iNOS in LPS stimulated macrophage cells, suggesting that decrease in NO production in the presence of P-SRD was the result of iNOS mRNA inhibition. These results indicate that N-palmitoylation of SRD may effectively ameliorate potentially fatal symptoms of LPS-induced endotoxemic hypotensive shock associated with IL-1 without inflammatory and pyrogenic toxic side effects.

Radioprotection, pharmacokinetic and behavioural studies in mouse implanted with biodegradable drug (amifostine) pellets

PURPOSE

We evaluated the use of a subcutaneously (s.c.) implantable, biodegradable pellet as a drug delivery system for the radioprotector amifostine.

MATERIALS AND METHODS

Mice were implanted s.c. with either the custom-made biodegradable amifostine drug pellet or the placebo pellet without amifostine, exposed to cobalt-60 gamma-radiation (bilateral, 1 Gy min(-1), 7-16 Gy), and the 30-day survival rate was monitored. The non-irradiated mouse was used for pharmacokinetic and behavioural tests.

RESULTS

Significant radioprotection (85-95% survival) at 10 Gy was observed in the three-amifostine pellet implanted group 3-5 h after implantation. LD50/30 was 7.97, 8.74 and 16.64 Gy for the control, three-placebo pellet (dose reduction factor, DRF=1.10, p<0.01), and three-amifostine pellet (DRF=1.79, p<0.01) groups respectively in mouse exposed to radiation 2h after implantation. Radioprotection at 12 Gy was observed up to 4h after s.c. amifostine administration and up to 3h after implantation. Pharmacokinetic data revealed that the three-amifostine pellet group had sustained blood WR-1065 levels at 2 h after implantation, in contrast to the reported sharp peak at 30 min for s.c. administration. Although locomotor activity was significantly reduced (p<0.01) in the amifostine pellet group, the onset of the locomotor decrement was delayed as compared with groups that received 400 and 750 mg kg(-1) s.c. amifostine.

CONCLUSIONS

Amifostine in biodegradable implant was effective. The radioprotection observed was comparable between conventional s.c. administration of the drug and implantation. Pharmacokinetic data and locomotor activity suggest that the implantation was beneficial though radioprotection data warrants formulation improvements in implants.

Hematopoietic responses under protracted exposures to low daily dose gamma irradiation

In attempting to evaluate the possible health consequences of chronic ionizing radiation exposure during extended space travel (e.g., Mars Mission), ground-based experimental studies of the clinical and pathological responses of canines under low daily doses of 60Co gamma irradiation (0.3-26.3 cGy d-1) have been examined. Specific reference was given to responses of the blood forming system. Results suggest that the daily dose rate of 7.5 cGy d-1 represents a threshold below which the hematopoietic system can retain either partial or full trilineal cell-producing capacity (erythropoiesis, myelopoiesis, and megakaryopoiesis) for extended periods of exposure (>1 yr). Trilineal capacity was fully retained for several years of exposure at the lowest dose-rate tested (0.3 cGy d-1) but was completely lost within several hundred days at the highest dose-rate (26.3 cGy d-1). Retention of hematopoietic capacity under chronic exposure has been demonstrated to be mediated by hematopoietic progenitors with acquired radioresistance and repair functions, altered cytogenetics, and cell-cycle characteristics. Radiological, biological, and temporal parameters responsible for these vital acquisitions by hematopoietic progenitors have been partially characterized. These parameters, along with threshold responses, are described and discussed in relation to potential health risks of the space traveler under chronic stress of low-dose irradiation.

In vivo radioprotection by 5-androstenediol: stimulation of the innate immune system

We showed previously that 5-androstenediol stimulates myelopoiesis, increases the numbers of circulating neutrophils and platelets, and enhances resistance to infection in gamma-irradiated mice. We have extended those studies to include monocytes, natural killer (NK) cells, eosinophils and basophils, and we have measured the activation marker CD11b using flow cytometry. Androstenediol (160 mg/kg) was administered subcutaneously to female B6D2F1 mice 24 h before whole-body gamma irradiation. Androstenediol treatments increased the blood levels of neutrophils, monocytes and NK cells in unirradiated animals; decreased the numbers of circulating eosinophils; and ameliorated radiation-induced decreases in neutrophils, monocytes, NK cells, erythrocytes and platelets. The androstenediol treatments had no significant effect on the numbers of circulating B cells or T cells. CD11b labeling intensity on monocytes was decreased slightly after androstenediol treatment. In contrast, radiation or androstenediol alone caused increases in CD11b labeling intensity on NK cells. Androstenediol and radiation combined caused a marked increase in NK cell CD11b. The results indicate that androstenediol increases the numbers of the three major cell types of the innate immune system (neutrophils, monocytes and NK cells), that androstenediol-induced changes in blood elements in irradiated animals persist for at least several weeks, and that there is a significant positive interaction between radiation and administration of androstenediol in the activation of NK cells.

Androstenediol stimulates myelopoiesis and enhances resistance to infection in gamma-irradiated mice

The ionizing radiation-induced hemopoietic syndrome is characterized by defects in immune function and increased mortality due to infections and hemorrhage. Since the steroid 5-androstene-3beta, 17beta-diol (5-androstenediol, AED) modulates cytokine expression and increases resistance to bacterial and viral infections in rodents, we tested its ability to promote survival after whole-body ionizing radiation in mice. In unirradiated female B6D2F1 mice, sc AED elevated numbers of circulating neutrophils and platelets and induced proliferation of neutrophil progenitors in bone marrow. In mice exposed to whole-body (60)Co gamma-radiation (3 Gy), AED injected 1 h later ameliorated radiation-induced decreases in circulating neutrophils and platelets and marrow granulocyte-macrophage colony-forming cells, but had no effect on total numbers of circulating lymphocytes or erythrocytes. In mice irradiated (0, 1 or 3 Gy) and inoculated four days later with Klebsiella pneumoniae, AED injected 2 h after irradiation enhanced 30-d survival. Injecting AED 24 h before irradiation or 2 h after irradiation increased survival to approximately the same extent. In K. pneumoniae-inoculated mice (irradiated at 3-7 Gy) and uninoculated mice (irradiated at 8-12 Gy), AED (160 mg/kg) injected 24 h before irradiation significantly promoted survival with dose reduction factors (DRFs) of 1.18 and 1.26, respectively. 5-Androstene-3beta-ol-17-one (dehydroepiandrosterone, DHEA) was markedly less efficacious than AED in augmenting survival, indicating specificity. These results demonstrate for the first time that a DHEA-related steroid stimulates myelopoiesis, and ameliorates neutropenia and thrombocytopenia and enhances resistance to infection after exposure of animals to ionizing radiation.

Hematopoietic tissue repair under chronic low daily dose irradiation

The capacity of the hematopoietic system to repair constantly accruing cellular damage under chronic, low daily dose gamma irradiation is essential for the maintenance of a functional hematopoietic system, and, in turn, long term survival. In certain individuals, however, such continuous cycles of damage and repair provide an essential inductive environment for selected types of hematopathologies, e.g., myeloid leukemia (ML). In our laboratory we have been studying temporal and causal relationships between hematopoietic capacity, associated repair functions, and propensities for hematologic disease in canines under variable levels of chronic radiation stress (0.3-26.3 cGy d-1). Results indicate that the maximum exposure rate tolerated by the hematopoietic system is highly individual-specific (three major responding subgroups identified) and is based largely on the degree to which repair capacity, and, in turn, hematopoietic restoration, is augmented under chronic exposure. In low-tolerance individuals (prone to aplastic anemia, subgroup 1), the failure to augment basic repair functions seemingly results in a progressive accumulation of genetic and cellular damage within vital progenitorial marrow compartments (particularly marked within erythroid compartments) that results in loss of reproductive capacity and ultimately in collapse of the hematopoietic system. The high-tolerance individuals (radioaccomodated and either prone- or not prone to ML, subgroup 2 & 3) appear to minimize the accumulating damage effect of daily exposures by extending repair functions, which preserves reproductive integrity and fosters regenerative hematopoietic responses. As the strength of the regenerative response manifests the extent of repair augmentation, the relatively strong response of high- tolerance individuals progressing to patent ML suggests an insufficiency of repair quality rather than repair quantity. The kinetics of these repair-mediated, regenerative hematopoietic responses within the major subgroups are under study and should provide useful insights into the nature of hematopoietic accommodation (or its failure) under greatly extended periods of chronic, low-daily-dose ionizing radiation exposure.

Response of hemopoiesis in dogs to continuous low dose rate total body irradiation

Among the cytotoxic agents which particularly cause damage to cell renewal systems, ionizing radiation is one of the most effective ones since it leads to inactivation of all types of proliferating cells including resting stem cells. It is the aim of this paper to present the effects of continuous low dose rate total body irradiation (TBI) on hemopoiesis in dogs. The animals were exposed to gamma-rays from a 60-Co source, receiving a daily radiation dose of 0.0188 Gy for indefinite times. Sequential hematological studies performed included determinations of peripheral blood cell counts and of total cell numbers in standardized bone marrow samples, assessments of progenitor cells GM-CFC in the blood and bone marrow, and of colony-stimulating activity (CSA) in the serum. The lymphocytes, the thrombocytes and neutrophilic granulocytes uniformly showed early decreases within the first 200 to 500 days corresponding to cumulative radiation doses in the range up to 3.8 to 9 Gy, but remained stable at subnormal levels in the period up to 1,700 days of exposure. The GM-CFC numbers in bone marrow samples from the rib clearly showed a strong decrease within the first 150 days of exposure preceding the changes in the blood granulocyte concentration. A transient partial recovery of the GM-CFC was observed at later times between 700 and 1,200 days of exposure, followed by another decrease to extremely low values at cumulative doses in the range of 32 Gy.(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic radiation-induced alteration in hematopoietic repair during preclinical phases of aplastic anemia and myeloproliferative disease: assessing unscheduled DNA synthesis responses

Protracted, low-daily-dose gamma-ray exposure (3.8-7.5 cGy/day) segregates canines into separate survival- and pathology-based subgroups by the early elicitation of distinct, repair-mediated hemopathological response pathways. In this study, we verified the blood and marrow responses of two major subgroups prone to either aplastic anemia or myeloproliferative disease, along with two variants, and extended our analyses of hematopoietic repair to include studies of DNA repair in bone marrow blasts using an autoradiographically based unscheduled DNA synthesis (UDS) assay. The myeloproliferative disease-prone subgroup exhibited extended survival (> 200 days), related to partial, gradual restoration of blood leukocyte, platelet, and marrow progenitor levels following an initial phase of acute suppression. Marrow blasts taken during the restoration phase showed expanded and qualitatively modified UDS relative to marrow blasts of age-matched control animals. The amount of UDS per blast (signal strength) increased significantly, as did the number of UDS-positive cells and their sensitivities to high-dose UV induction and 1-beta-D-arabinofuranosylcytosine chemical inhibition. A nonevolving myeloproliferative disease-prone variant having prolonged survival (> 200 days) and restored blood cells and marrow progenitor levels also had marrow blasts with expanded UDS responses, but these were uniquely evoked by low (but not high) doses of UV inducer. The aplastic anemia-prone subgroup was characterized by short survival (< 200 days), progressive decline (without restoration) in all measured blood and marrow compartments, and largely nonsignificant changes in UDS responses of marrow blasts. A variant of this aplastic anemia-prone subgroup (with comparable short survival due to markedly ineffective hematopoiesis, but expressing select preleukemic features) exhibited reduced numbers (relative to age-matched controls) of highly responsive, UDS-positive marrow blasts (in terms of UDS signal strength and increased to sensitivity 1-beta-D-arabinofuranosylcytosine-induced UDS inhibition). From these observations we conclude that: (a) the UDS response of marrow blasts, a correlate of hematopoietic progenitorial repair, is altered differentially within selected subgroups of animals under chronic radiation exposure; and (b) the nature of altered UDS repair response patterns appears to be largely related to the preclinical status/predisposition of the individual animal and thus may provide prognostically useful information in the clinical monitoring of chronically irradiated individuals with minimal but evolving hematological disease.

5,8,11,14-eicosatetraynoic acid-induced destruction of mitochondria in human prostate cells (PC-3)

Culturing human prostate PC-3 cells for 4, 24, or 72 h in the presence of 5,8,11,14-eicosatetraynoic acid (ETYA), an inhibitor of arachidonic acid metabolism and cholesterol biosynthesis, markedly altered the morphology and reduced the number of mitochondria in the treated cells. Using quantitative electron microscopic morphometry, we documented changes in the number, form, area, matrix density, and integrity of the cristae and limiting membranes of mitochondria in cells cultured with ETYA. The inhibition of cholesterol synthesis or the substitution of ETYA for polyunsaturated fatty acids in the inner membrane may participate in the disruption of the mitochondria, which resembles the morphologic sequelae of oxidative stress. If sufficiently extensive, these changes could contribute to the inhibition of cellular proliferation by ETYA.

Acquired radioresistance of hematopoietic progenitors (granulocyte/monocyte colony-forming units) during chronic radiation leukemogenesis

Protracted exposure of dogs to low daily doses of whole-body gamma-radiation (7.5 cGy/day for duration of life) elicits a high incidence of myeloid leukemia or related myeloproliferative disorders. Under such exposure, vital hematopoietic progenitors [granulocyte/monocyte colony-forming units in agar (CFU-GM)] acquire increased radioresistance along with renewed proliferative capacity at an early phase of evolving myeloid leukemia. To further characterize the expression of acquired radioresistance by CFU-GM, we evaluated the effects of various exposure rates, cumulative radiation doses, and times of exposure and postexposure in several groups of long-lived dogs under two conditions of irradiation: (a) continuous, duration-of-life exposures at dose rates of 0.3-7.5 cGy/day; and (b) discontinuous, fraction-of-life exposures at dose rates of 3.8-26.3 cGy/day, with cumulative doses of 450-3458 cGy and postexposure times of 14-4702 days. Results indicated that (a) under protracted continuous irradiation, the degree of radioresistance expressed by CFU-GM in vitro increased markedly in a biphasic pattern with rising daily rates of exposure; (b) under discontinuous, fraction-of-life exposure regimens, elevated levels of radioresistance were expressed and stably maintained by CFU-GM only following large radiation doses accumulated at high dose rates; and (c) with extended postexposure times, the magnitude of expressed radioresistance appeared to wane. These results continue to support the hypothesis that the acquisition of radioresistance and associated repair functions by vital lineage-committed progenitors, under the strong selective and mutagenic pressure of chronic irradiation, is tied temporally and causally to leukemogenic transformation elicited by radiation exposure.

Differential effects of ETYA, a PUFA-analogue, on prostate (PC3) and monoblastoid U937 ultrastructure; lack of correlation with reduced proliferation

ETYA (5,8,11,14-eicosatetraynoic acid), a polyunsaturated fatty acid analogue, inhibits proliferation of PC3 and U937 cells and induces a limited differentiation in U937 cells. Human prostate PC3 cells cultured for 72 h with 40 microM ETYA in fetal calf serum contained putative lipofuscin bodies, myelin figures and mitochondria with damaged cristae and matrices. These changes were absent from human U937 monoblastoid cells incubated with ETYA in CPSR3, a semipurified serum replacement. U937 cells cultured with ETYA in fetal calf serum contained occasional lipofuscin bodies, while PC3 cells cultured in CPSR3 exhibited all of the changes described. ETYA reduced the oxygen consumption of both cell lines. Therefore we conclude: (a) The response to ETYA by cells of dissimilar developmental origin is not identical; (b) unidentified serum components can augment potential ETYA-induced oxidative stress-responses of cells; (c) inhibition of U937 proliferation by ETYA does not depend upon the morphologic changes seen in PC3 cells, which resemble sequelae of oxidative stress with excess free radicals; and (d) rapid ETYA-induced inhibition of oxygen consumption in both cell lines implies a reduced synthesis of ATP that could contribute to the reversible impairment of cellular proliferation.

Probing altered hematopoietic progenitor cells of preleukemic dogs with JANUS fission neutrons

Protracted courses of low-daily-dose gamma irradiation elicit high incidences of myeloproliferative disease, principally myeloid leukemia (ML), in beagle dogs. A four-phase preclinical sequence in the induction of ML has been described: (1) suppression, (2) recovery, (3) accommodation, and (4) preleukemic transition. Within this sequence, a critical "early"-occurring hematopoietic target cell event that promotes progression of preclinical phases I and II has been identified and characterized by an acquisition of increased radioresistance to low-LET gamma rays by granulocyte/monocyte lineage-committed progenitor cells (CFU-GM). To gain further insight into the basis of this critical event, the acquired survival response of preleukemic progenitor cells has been probed in vitro with high-LET fission neutrons. For these studies, marrow CFU-GM were isolated from chronically irradiated preleukemic dogs, as well as from nonirradiated controls, subjected to graded doses (0-300 cGy) of either JANUS fission neutrons or 60Co gamma rays, and assayed for survival by a standard cloning assay. Major observations resulting from these assays include the following. First, the acquired radioresistance of preleukemic CFU-GM to low-LET gamma rays noted previously extends to high-LET fission neutrons as well. Relative to control CFU-GM exhibited small but significant increases in radioresistance of about 10 cGy with an average D0 value of 38 (+/- 2.3) cGy for preleukemic CFU-GM, and 28 (+/- 1.3) cGy for the control levels, the CFU-GM irradiated within a marrow dose range of 10-75 cGy. Second, at higher neutron doses (150-600 cGy), fractional survival of both control and preleukemic CFU-GM declined nonexponentially, suggesting the existence of a small, radioresistant subpopulation constituting about 2% of the total marrow CFU-GM within normal nonirradiated dogs, and a 15% fraction of the progenitor cell population in preleukemic marrow (preclinical phases II-IV). The latter is most likely the result of a normally minor subpopulation gaining a growth advantage due to its inherent radioresistance and clonally expanding in the strong selective pressure of chronic marrow irradiation in vivo. We speculate that these qualitative/quantitative changes in the function of progenitor cells foster the initiation of aberrant regenerative hematopoiesis characteristic of early evolving radiation leukemogenesis.

Alpha-particle irradiation-induced change in bronchopulmonary macrophage morphology, in vitro

Bronchopulmonary macrophages, isolated from canine lungs by saline lavage and grown in tissue culture for short periods, were acutely irradiated with a range of doses of either Americium-241 alpha particles (0.03-48 Gy) or 250 keV x-rays (0.5-24 Gy). Following a 24-hour reincubation and "expression" period, cells were examined for radiation-induced changes in overall viability, as well as in cell morphology and ultrastructure. Results indicated that neither quality of radiation had much effect on cell viability over dose ranges examined, but substantial changes in cell volume, surface topography, and cytoplasmic features were noted, especially in the alpha-particle-irradiated specimens. Results support the concept that the limiting plasma membrane of the targeted macrophage is a sensitive subcellular target for ionizing radiation, especially high-linear-energy-transfer heavy particles.

Ultrastructural evidence for differentiation in a human glioblastoma cell line treated with inhibitors of eicosanoid metabolism

Human glioblastoma cells incubated in the presence of inhibitors of eicosanoid biosynthesis show decreased cellular proliferation without cytotoxicity. We studied the ultrastructural morphology of a human glioblastoma cell line cultured with nordihydroguaiaretic acid (NDGA), a lipoxygenase inhibitor, or 5,8,11,14-eicosatetraynoic acid, a cyclooxygenase and lipoxygenase inhibitor. When glioblastoma cells were treated for 3 days with antiproliferative concentrations of either agent, they shared many morphological characteristics, including evidence for increased astrocytic differentiation with only limited signs of toxicity. The inhibited glioma cells demonstrated an increase in the number and length of astrocytic processes containing greater numbers of glial filaments, and the NDGA-treated cells also demonstrated extensive lateral pseudopod formation along the processes. The glioblastoma cell shape also became more elongated, losing the usual nuclear lobularity and nuclear inclusions, especially in NDGA-treated cells. Many cytoplasmic organelles packed the cytosol of the inhibited glioma cells, including prominent Golgi apparatus, dilated smooth endoplasmic reticulum evolving into dilated vesicles, cytoplasmic vacuoles, and numerous concentric laminations. There was limited evidence for toxicity, however, as the mitochondria were more pleomorphic with some mitochondrial distention and disruption of the cristae along with an increase in cytoplasmic vacuolization. We conclude that the inhibitors of eicosanoid biosynthesis, NDGA and 5,8,11,14-eicosatetraynoic acid, not only suppress glioblastoma cell proliferation, but also induce increased astrocytic differentiation.

Changing patterns of radiosensitivity of hematopoietic progenitors from chronically irradiated dogs prone either to aplastic anemia or to myeloproliferative disease

Hematopoietic patterns have been assessed in chronic 60Co gamma irradiated dogs during preclinical phases of evolving aplastic anemia (AA) or myeloproliferative disease (MPD), principally myeloid leukemia. Within the AA-prone dog, a singular phase of progressive decline in blood levels of granulocytes and monocytes was noted along with a similar reduction in marrow progenitors committed to granulocyte/monocyte differentiation (CFU-GM). Measured radioresistance of the preAA CFU-GM in vitro, relative to control CFU-GM from nonirradiated animals, revealed only slightly increased resistance to gamma rays, but significantly increased resistance to fission neutrons. Within the MPD-prone dogs, four preclinical phases (i.e. suppression, partial recovery, accommodation, and preleukemic transition) preceding development of overt MPD were evidenced by the monitored change in blood granulocyte/monocyte counts and marrow progenitor levels. Analysis of radioresistance of preMPD CFU-GM revealed marked changes with time of exposure and, in turn, with preclinical phase transitions. Gamma ray resistance increased in the initial phases of exposure, with maximal levels occurring during the middle phase of exposure (accommodation, phase III) followed by a tailing off of resistance at later times. Resistance to fission neutrons by preMPD CFU-GM was observed as well, but somewhat later in the exposure course and at a much lower, more consistent level. These differential patterns of radioresistance expressed by marrow CFU-GM of chronically irradiated MPD-prone dogs to gamma rays and fission neutrons gave rise to preclinical phase-specific 'relative biological effectiveness' (RBE) values. From these observations, we conclude that: (i) CFU-GM of MPD-prone dogs acquire and maintain marked radioresistance to low linear energy transfer (LET) gamma rays, but only marginally elevated radioresistance to high-LET fission neutrons during the course of chronic gamma ray exposure; and (ii) CFU-GM of the AA-prone dog, in contrast, acquire little change in resistance to gamma rays, but, surprisingly, marked resistance to neutrons relative to progenitors from nonirradiated controls. These results support the concept that acquired radioresistance of vital granulocyte/monocyte lineage-committed hematopoietic progenitors is temporally, perhaps causally, linked to the processes mediating hematopoietic recovery and accommodation under chronic irradiation, and in turn to preclinical events of evolving MPD. In addition, the marked differential responses of progenitors to gamma and neutron irradiation in vitro might suggest differences in the nature of cellular lesions elicited by chronic gamma irradiation, in vivo.

Blood responses under chronic low daily dose gamma irradiation: I. Differential preclinical responses of irradiated male dogs in progression to either aplastic anemia or myeloproliferative disease

Male beagles chronically exposed to low daily doses of 60Co gamma rays (7.5 cGy/22h/day) show one of three hematopoietic patterns, which reflect three different distinctly responding subgroups: (1) low radioresistance with progressing aplastic anemia and shortened survival (-S-AA subgroup); (2) high radioresistance with a complex of progressing myeloproliferative disorders (+R-MPD group); or (3) high radioresistance with other nonMPD syndromes (+R-nonMPD group). Blood cell levels (granulocytes, monocytes, erythrocytes, lymphocytes, and platelets) were assessed and fitted to a flexible polynomial spline model, thus defining the (a) initial suppressive and (b) subsequent recovery phases for the subgroups. Results showed that relative to the overall magnitude of blood cell loss as well as to the maximum rate of suppression during the initial phase, the subgroups were generally ranked -S-AA much greater than +R-MPD greater than +R-nonMPD. Relative to the overall strength of the recovery response, the subgroups were generally ranked +R-MPD greater than +R-nonMPD much much greater than -S-AA. In terms of overall maintenance levels of circulating blood cells during the recovery phase, however, the +R-nonMPD subgroup consistently exhibited stronger responses than the +R-MPD subgroup. These results tend to support our contention that selected subgroups of dogs have strong propensities to specific hematopathologies (i.e. aplastic anemia and myeloid leukemia) under chronic irradiation and that these pathology-prone animals exhibit a series of marked differential hematopoietic responses during early preclinical phases, which serve effectively to prognosticate subsequent pathological progression.

The ultrastructure of hematopoietic stroma on cellulose ester membranes implanted intraperitoneally into Sl/Sld and Sl+/Sl+ mice

The structural features of hematopoietic stromal elements forming on cellulose ester membranes (CEM) implanted intraperitoneally into hematopoietically impaired, anemic Sl/Sld mice and their normal Sl+/Sl+ littermates were compared by combined light and electron microscopy. The generally thicker, multilayered stroma lining the Sl+/Sl+ CEM implants developed from a bed--a syncytium--of large, highly pleomorphic macrophage-type lining cells whose filopodial extensions exhibited extensive interactions (i.e., nurse cell interactions) with both stromal and hematopoietic elements. In contrast, the thinner stromal layers lining the CEM of Sl/Sld mice formed from a base of dysplastic lining elements. These CEM-lining macrophage-type cells had much reduced cytoplasmic volumes, less extensive interactive surface projections, and an absence of select types of cytoplasmic organelles (e.g., membrane-bound crystalline inclusions). These observations suggest that the reduction of cell layering and, in turn, hematopoietic support activity, is due to an impaired interactive capacity of these elemental lining cells, i.e., pleomorphic macrophagic cell types, in the hematopoietically impaired strain of Sl/Sld mice.

Developmental and radiobiologic characteristics of canine multinucleated, osteoclast-like cells generated in vitro from canine bone marrow

We report here our initial observations on the growth and morphology, and developmental radiosensitivity of giant, multinucleated, osteoclast-like cells (MN-OS) generated through in vitro cultivation of hematopoietic progenitor-enriched canine bone marrow samples. Maximum cell densities of 5.5 x 10(3) to 6.5 x 10(3) MN-OS per cm2 of growth area were achieved following 10 to 14 days of culture at 37 degrees C. Acute gamma irradiation of the initial marrow inocula resulted in significant, dose-dependent perturbations of MN-OS formation, growth, and development. Attempts to estimate radiosensitivity of MN-OS progenitors from canine marrow yielded a range of Do values from a low of 212 cGy measured at six days of culture to higher values of 405 to 542 cGy following 10 to 22 days of culture. At the intermediate times of culture (10 to 14 days), the radiation-induced responses were clearly biphasic, reflecting either (a) the presence of multiple subpopulations of MN-OS progenitors with varying degrees of radiosensitivity or (b) the inherent biphasic nature of MN-OS development involving early progenitor cell proliferation followed by maturation and subsequent fusion. Morphologically, MN-OS generated from irradiated marrow inocula appeared only marginally altered, with alterations expressed largely in a biphasic, dose-dependent fashion in terms of smaller cell size, reduced number of nuclei, increased expression of both surface microprojections, and a unique set of crystalloid cytoplasmic inclusions. Functionally, MN-OS appeared to be impaired by irradiation of marrow progenitors, as evidenced by failure to initiate resorptive attachments to devitalized bone spicules in vitro.

SEM of canine chromosomes: normal structure and the effects of whole-body irradiation

Canine chromosomes are not only numerous (38 autosomal pairs), but they are small (compared to human chromosomes) and morphologically similar as well. Analysis of the canine karyotype by light microscopy (LM) of banded chromosomes is, thus, difficult, and the literature on the canine karyotype is scanty. In this study, we describe examination of chromosomes from normal and chronically irradiated dogs with the scanning electron microscope (SEM). Metaphase chromosomes from bone marrow aspirates were Giemsa-banded with either 0.025% trypsin alone or 0.1% trypsin preceded by 10% H2O2 and prepared for SEM. Examination of chromosomes from normal dogs revealed cylindrical chromosome profiles with well-defined chromatids and centromeres. The chromosome arms were consistently marked by periodic grooves that had complementary structures on sister chromatids and may represent the trypsin-sensitive chromatic regions. The quality of the preservation varied from preparation to preparation and depended on the concentration and time of trypsin treatment. Chromosomes from irradiated dogs revealed translocations, deletions, and gaps. We conclude that SEM produces images superior to LM images of canine chromosomes; SEM images can be used not only to identify individual chromosomes, but also to identify genetic lesions in the chromosomes of chronically irradiated dogs. We further conclude that the two Giemsa-banding protocols used in the present study produced variable results, although 0.025% trypsin alone appeared to give better and more consistent results than 0.1% trypsin preceded by 10% H2O2.

Structure-function relationships in radiation-induced cell and tissue lesions: special references to the contributions of scanning electron microscopy and hematopoietic tissue responses

Contributions of scanning electron microscopy to the field of radiation biology are briefly reviewed and presented in terms of an overall goal to identify and characterize the structural features of radiation-induced lesions in vital cell and tissue targets. In the context of "lesion" production, the major radiation-elicited response sequences, the types and nature of measured end points, and governing temporal and radiobiological parameters are discussed and illustrated by using results derived from both in vitro cell systems and in vivo studies that measured tissue responses from various organ systems (respiratory, digestive, circulatory, and central nervous systems). Work in our laboratory on the nature of early and late hematopathologic tissue responses (aplastic anemia and myeloid leukemia) induced by protracted radiation exposure and the "bridging effect" of repair processes relative to the expression of these pathologies is highlighted.

Chronic radiation leukemogenesis: postnatal hematopathologic effects resulting from in-utero irradiation

Previous studies have shown that continuous whole-body exposure to low daily doses of gamma radiation is highly leukemogenic for beagles initially exposed during either young adulthood or fetal development. In contrast, terminated radiation-exposure regimens (continuous exposure terminated after accumulation of preset total radiation doses) markedly reduce leukemogenic potential. In this study, we examined leukemic incidences and postnatal hematopoietic function in three groups of dogs; continuously irradiated (7.5 cGy/day) during both fetal life and after birth, continuously irradiated during fetal life only, and nonirradiated. Results were compared to results from studies with similarly irradiated and nonirradiated groups of young adult dogs initially tested at 400 days of age. Hematopoietic function was assessed in terms of both circulating blood levels of red cells, platelets, granulocytes, and monocytes, and marrow concentrations and radiosensitivities of hematopoietic progenitors. Results indicated that under continuous fetal/postnatal irradiation, i.e. the high leukemogenic exposure regimen, a marked, progressive suppression in hematopoietic function occurred following birth. This suppression continued to 100-150 days of age and was followed by partial hematopoietic recovery that was associated with an acquired radioresistance by hematopoietic progenitors. In contrast, neonates that had been continuously irradiated during fetal life, but not postnatally, i.e. the low leukemogenic regimen, exhibited a similar initial suppression of hematopoietic function followed by partial recovery. However, no temporally linked acquisition of radioresistance by hematopoietic progenitors was demonstrated. These results support the hypothesis, developed from earlier studies with adult dogs, that the processes of acquired radioresistance and recovery in numbers of transformable hematopoietic progenitors are causally linked to early stages of the leukemogenic process under continuous ionizing irradiation.

Hematopoiesis on cellulose ester membranes: VII. Ultrastructure of stroma of marrow-enriched membranes with trilineal hematopoiesis

The ultrastructure of developing osseous and hematopoietic tissue and supporting stroma was examined within intraperitoneally implanted, marrow-coated cellulose ester membranes (CEMs). During initial periods of implantation (two weeks), coated CEMs were shallowly infiltrated and surface-lined with mainly two stromal cell types--primitive mesenchymal cells and large, pleomorphic, multinucleated monocytoid-like stromal cells--and, in addition, endothelial cells in early stages of vessel development. Selective proliferation, maturation, and orientation of these cell types along the CEM's surface (one month), resulted in the formation of primitive osseous and hematopoietic tissue sites. Osseous sites developed as undifferentiated mesenchymal cells transformed into well-differentiated secretory cells residing in an electron-dense, pre-mineralized extracellular matrix, that upon extended implantation (3-6 months) formed bone. Hematopoietic sites developed as mesenchymal cells, in intimate contact with the monocytoid-like stromal cells, extended elongated branches into the medullary cavity, and enveloped newly formed surface-associated vascular structures. With subsequent maturation of vascular sinuses and supporting adventitial stroma (3-6 months), the sites were colonized with either uni-, bi-, or trilineal hematopoietic elements. These observations provide evidence that common, marrow-derived precursor stromal cells, i.e., mesenchymal and multinucleated monocytoid-like cells, cooperate in the development of both osseous and hemic tissue sites.

CFU-GM colony-enhancing activity in sera of dogs under acute and chronic gamma-irradiation regimens

Dogs were chronically irradiated (10 R/day; 0-400 R) or acutely irradiated (20 R/min; 0-400 R) with 60Co gamma-rays. Sera were collected and assayed for colony-enhancing activity by a double-layer agar cloning technique. When test sera alone were incorporated in the feeder layers, no colony-forming units-granulocyte/macrophage formation occurred; the addition of peripheral blood leukocytes to such test sera-containing feeder layers resulted in formation of colonies, the number of which was directly related to the cumulative radiation dose. Serum-enhancing factor activity indirectly increased colony formation by stimulating feeder layer leukocytes to generate increased levels of colony-stimulating activity. Levels of serum-enhancing activity were higher at similar dose levels following acute gamma irradiation then following chronic irradiation.

Phospholipid-nucleoside conjugates. The aggregational characteristics and morphological aspects of selected 1-beta-D-arabinofuranosylcytosine 5'-diphosphate-L-1,2-diacylglycerols

1-beta-D-Arabinofuranosylcytosine 5'-diphosphate-1,2-diacylglycerols have previously been shown to be promising candidates as prodrugs of the clinically useful antileukemic agent 1-beta-D-arabinofuranosylcytosine. Because of the amphipathic nature of these liponucleotides and the potential that their morphological state may mediate their biological activity, it was necessary to undertake detailed studies of their aggregational and morphological characteristics. When samples of 1-beta-D-arabinofuranosylcytosine 5'-diphosphate-L-1,2-diacylglycerols (containing either dimyristoyl, dipalmitoyl or distearoyl fatty acid side chains) were prepared in buffered saline solutions using sonication methods, the morphological nature of the resulting aggregate was shown to be related to temperature and the length of the side chain. When sonicated at low temperatures all the above-mentioned derivatives gave turbid solutions containing large bilayer sheets. As the temperature was raised, a transition temperature was reached at which a stable three-dimensional cross-linked network of small interlocking bilayer stacks was formed. This turbidity transition temperature was directly related to the chain length of the fatty acid side chain. Sonication at temperatures close to this turbidity transition temperature produced small disc-shaped micellar structures. These micelles were shown to exist in another aggregational equilibrium consisting of a stacking-destacking process, the position within this equilibrium being dependent upon the concentration. In contrast, a sample of 1-beta-D-arabinofuranosylcytosine 5'-diphosphate-L-1,2-dioleoylglycerol (which contains an unsaturated carbon-carbon bond in each of the fatty acid side chains) was shown to give a multilamellar liposome structure when sonicated in buffered saline at temperatures above its turbidity transition temperature.

The ultrastructure of radiation-induced endosteal myelofibrosis in the dog

A rapidly developing, progressive form of endosteal myelofibrosis (MF) (with myeloid metaplasia) has been shown to occur at low frequency (approximately 4%) in dogs exposed continuously to low daily doses (10 R/day) of whole-body gamma irradiation. We report in this study the morphological details of the endosteal surface during both preclinical and clinical phases of developing MF by combination light microscopy and scanning/transmission electron microscopy. Pronounced alterations of the endosteum were observed and included: (1) during the early preclinical phases, a progressive time-dependent transition of the endosteal surface from predominantly resting to actively formative and resorptive states; and (2) during the late preclinical phase, aberrant autonomous osteogenic process(es) characterized by a marked reduction in the resorptive, osteoclast-associated endosteal areas occurring concomitantly with further increases in formative areas of the endosteum. Localized patches of overlapping, morphologically transformed endosteal cells (i.e., round-osteoblastic to branched-reticular shaped) were observed within the morphologically reactive, formative endosteum. Osteogenic-endosteal changes coincided with major restructuring of the hematopoietic parenchyma and supporting stromal network. We discuss the possibility that the early occurring endosteal changes are causally linked to normal reparative functions that operate during regenerative hematopoiesis following local and systemic injury. Based on morphological data collected during the late preclinical phase, we speculate that the mechanism of myelofibrosis induction involves the failure to terminate early osteogenic-dependent repair sequences.

Antiviral properties of polyinosinic acids containing thio and methyl substitutions

Polyinosinic acids containing methyl and sulphur substitutions are potent inhibitors of reverse transcriptase. Substitution of sulphur for oxygen at the 6 position produces significant effects on the properties of polyinosinic acid: the kinetics of inhibition change from competitive to mixed-type and the inhibition constant falls by three orders of magnitude. In contrast, 1-methyl substitution produces no such effects. Poly(1-methyl-6-thioinosinic acid) or poly(m1s6I) inhibits irreversibly, inhibiting all ten reverse transcriptases tested under a variety of assay conditions. In cell culture test systems, poly(m1s6I) is capable of blocking both infection by non-transforming viruses and transformation by a sarcoma virus. The presence of poly(m1s6I) in a preinfected culture results in the production of non-infectious virus particles lacking reverse transcriptase activity.

Hemopathologic consequences of protracted gamma irradiation: alterations in granulocyte reserves and granutocyte mobilization

Aplastic anemia and myelogenous leukemia are prominent pathologic effects in beagles exposed to continuous, daily, low-dose gamma irradiation. In the present work, granulocyte reserves and related mobilization functions have been sequentially assessed by the endotoxin stress assay during the preclinical and clinical phases of these hemopoietic disorders. Characteristic patterns of granulocyte reserve mobilization are described that reflect given stages of pathologic progression. For radiation-induced leukemia, a five stage pattern has been proposed. In contrast, a simple pattern of progressive, time-dependent contraction of granulocyte reserves and mobilization capacity was noted in the development of terminal aplastic anemia. Early preclinical phases of radiation-induced leukemia appear to involve an extensive depletion of the granulocyte reserves ((phase I) during the first approximately 200 days of exposure followed by a partial renewal of the reserves and associated mobilization functions approximately 200 and 400 days (phase II). Sustained, subnormal granulocyte mobilizations (phase III) following endotoxin stress typify the responses of dogs during the intermediate phase, whereas late preclinical, preleukemic stages (phase IV) are characterized by a further expansion of the reserves and in the mobilization capacities, particularly of the less mature granulocytes. Such late alterations in the pattern of granulocyte mobilization, together with other noted cellular aberrancies in the peripheral blood and marrow, appear to indicate leukemia (phase V) onset.

Colonization of Trypanosoma brucei gambiense within transplanted Ehrlich's tumors of Microtus montanus

Trypanosoma brucei gambiense has been observed growing in extravascular sites throughout a solid Ehrlich ascites tumor (EAT) in Microtus montanus. These trypanosomes appear in clusters in the tumor. The possible importance of this observation to the host-parasite relationship is discussed.

Acute monocytic leukemia in an irradiated Beagle

A purebred female Beagle dog that had received 2,000 R of protracted wholebody gamma-irradiation from 60Co when 14 months old had hematologic changes consistent with a myeloproliferative disorder 3 years after the termination of radiation exposure. Peripheral blood and bone marrow findings during the 7-month period before death showed progressive anemia with increased numbers of platelets; immature granulocytes, monocytes and promonocytes. A period of partial remission occurred during which time the peripheral blood was aleukemic, although there was marked thrombocytosis and abnormal erythropoiesis which was evidenced by bizarre circulating nucleated red cells, anisocytosis, poikilocytosis and Howell-Jolly bodies. The dog had a terminal crisis with marked leukocytosis, most cells in the peripheral blood being bizarre monocytes and promonocytes. Tissues obtained at necropsy showed diffuse as well as focal infiltration of the spleen, liver, lymph nodes, heart, kidney and gastrointestinal wall with immature neoplastic cells resembling monocytes and monocytic precursors. The monocytic differentiation of the invasive cell population was confirmed by morphological, cytochemical, histological, ultrastructural and in vitro cell culture studies.

Isolation and characterization of plasma membranes and intact nuclei from lymphoid cells

A method has been developed for the rapid large scale isolation of plasma membranes and intact nuclei from RAJI lymphoid cells utilizing hypotonic lysis of cells after intracellular loading with glycerol followed by combined flotation-sedimentation within a discontinuous sucrose gradient. Nuclei may be isolated in about 1 h and plasma membranes in about 6 h from 1 to 20 g of cells. Intact nuclei, obtained in 90 to 95% yield based on lysed cells, was isolated by differential centrifugation and contained 16% DNA and about 30% of total cell sialic acid. A crude plasma membrane fraction was isolated by centrifugation onto a cushion of 38% sucrose (d 1.1683) and subsequently resolved into two subfractions. The less dense vesicles had an average d 1.127 and showed a 7-fold increase in specific activity for thymidine phosphodiesterase while the more dense (d 1.151) had a 20-fold concentration of enzyme activity. Activity of enzymes indicative of contamination with lysosomes, microsomes, mitochondria, and cytoplasm was negligible in these plasma membrane fractions. The less dense vesicles had a cholesterol:phospholipid ratio of 0.97 which was higher than that of the more dense vesicles (0.69). Otherwise, the analytical values for the two types of membrane vesicles were similar as both fractions contained like percentages of protein (approximately 30%), lipid (approximately 30%), and carbohydrate (approximately 15%) with trace amounts of RNA and DNA. Twenty-five per cent of the total cell sialic acid was in the plasma membrane fractions.

Surface properties of extracellular malaria parasites: electrophoretic and lectin-binding characteristics

The surface charge and lectin-binding capacity of isolated malaria parasites and host erythrocytes were analyzed and compared by chromatographic, electrophoretic, and cytochemical methods. Results indicated that at physiological pH values both freshly prepared and glutaraldehyde-fixed parasites and erythrocytes possess a net negative surface charge. Both cell types were strongly bound to cation-exchange resins and underwent cathode-directed electrophoretic migration. The isoelectric points for erythrocyte-free parasites and uninfected erythrocytes were approximately 3.0 and 4.0, respectively. The different effects of selective enzymatic digestion and solvent extraction on the electrophoretic mobilities of free parasites and erythrocytes suggested that the chemical constituents responsibile for the net negative surface charges on each type of cell are different. The surface charge of the free parasites seemed mainly to be a function of ionized phospholipids rather than of the ionogenic sialic acid moieties, which are the major contributors to the negative charge on erythrocytes. Results of lectin-binding studies indicated that specific glycosidimoieties (i.e., glucose, galactose, mannose, and n-acetyglucosamine), common to the erythrocyte surface, were either absent or in low concentration at the parasite's surface. These observations suggest that the normally intracellular malaria parasites have surface characteristics, differing from those of the host cell, characterized by a scarcity of lectin-binding receptors and sialic acid residues and by the major contribution of lipids to their surface charge.

Surface properties of bloodstream Trypanosomes (Trypanosoma brucei)

The African trypanosome (Trypanosoma brucei brucei) in its bloodstream phase has been found to possess rather unique surface properties. Results of lectin and iron colloid binding studies have indicated that the parasite's surface coat is devoid of many types of exposed carbohydrate residues which commonly are expressed on a variety of mammalian cell types. These include: glucose, mannose, galactose, n-acetylglucosamine, n-acetylgalactosamine, and neuraminic acid. A number of these carbohydrates (E.G., glucose, mannose, galactose and n-acetylgalactosamine) are, however, buried within the surface coat as evidenced by lectin binding to trypsinized parasites. The surface of well preserved parasites also lack exposed sialic acid and phospholipid moieties. Moribund parasites (or trypsinzed organisms) with altered surface coats were found to possess well defined phospholipid regions, but not negatively charged sialyl residues. Results presented tend to suggest that carbohydrates and phospholipids are not present in the outermost portion of the glycocalyx, thus exerting little or no influence on surface-mediated biological activities. However, the presence of such components on the plasmalemma is presumed to be structurally significant; especially during those developmental phases where the glycocalyx is absent, i.e., fly midgut phase.

Plasmodium berghei: characteristics of a selected population of small free blood stage parasites

The characteristics of a selected population of small blood stage parasites obtained by differential centrifugation of a population of P. berghei parasites freed by continuous flow sonication are described. About 10% of these free parasites are merozoites, many others are transitional forms having some merozoite characteristics. The parasite preparations are infectious and sufficiently resistant to incubation at 37 degrees C to be useful experimentally. Disc gel electrophoresis analysis indicates that these small parasites differ in composition from an unselected intraerythrocytic P. berghei population.

Erythrocyte membrane alterations induced by Plasmodium simium infection in Saimiri sciureus: relation to Schüffner's dots

The nature of erythrocyte membrane alterations in Plasmodium simium infections was determined employing light microscopy, carbon replication and transmission electron microscopy. Light microscopy of Giemsa stained preparations shows that infected cells initially acquire a faint stippling (schuffnerization) which becomes pronouced with subsequent parasite development. Enlargement of the host cell usually accompanied stippling. Both phenomena appear to depend on host cell age since infected mature erythrocytes were neither stippled nor enlarged. Carbon replicas show numerous indentations over the outer membrane surface of most infected cells. Their distribution suggests that they account for Schuffner's granules. The surface indentations are manifest as small infundibular which open to the infected cell's surface. Cytoplasmic microvesciles in the infected cell's stroma frequently are observed adjacent or catenated to the surface infundibula. Images suggest their funsion with the surface infundibula thus adding membrane to the cell's surface and accounting for host cell enlargement.