Persisting multilineage transgene expression in the clonal progeny of a hematopoietic stem cell.

Many applications of hematopoietic gene therapy require selection for clones with active transgene expression. However, it was unclear whether the clonal progeny of a retrovirally transduced hematopoietic stem cell would be capable of maintaining transgene expression through serial repopulation and multilineage differentiation. Such investigations require simultaneous analyses of clonality, multilineage activity and transgene copy numbers. Using a mouse model, the present study demonstrates that a single hematopoietic stem cell expressing a marker gene from one or two insertions of a simple retroviral vector actively maintains multilineage transgene expression in the vast majority (80-99%) of bone marrow and peripheral blood cells. Gene expression persisted through serial transplantations for at least 97 weeks post gene transfer and was observed in the lymphoid (B, T and NK cells), myeloid (CD11b(+), Gr-1(+)), erythroid (Ter119(+), mature red blood cells) and megakaryocytic (as indicated by platelets) progeny. Therefore, a single immunoselection for hematopoietic stem cells expressing the transgene in vivo was sufficient to establish a completely chimeric hematopoiesis. These observations imply that the retroviral vectors used in this study contain cis-elements that mediate expression through massive clonal expansion and multilineage differentiation, provided the insertion occurred in genetic loci permissive for expression in hematopoietic stem cells.

Lectin histochemistry of the spleen: a new lectin visualizes the stromal architecture of white pulp and the sinuses of red pulp.

The subcompartmentalization of the white pulp in the spleen is the result of interactions of specific resident stromal cells and migrating subtypes of lymphocytes. Because carbohydrate residues of cell membranes and extracellular matrices are involved in cell-cell and cell-matrix interactions, they were investigated in rat spleen by a broad panel of lectins. Splenic macrophages, which were also demonstrated by Perls' Prussian blue reaction, were labeled selectively by most mannose-specific lectins and gave the characteristic distribution patterns in all splenic (sub)compartments. One recently isolated lectin, Chelidonium majus agglutinin (CMA), visualized predominantly central arterioles, the reticular meshwork (RM) in the periarteriolar lymphatic sheaths (PALS), the circumferential reticulum cells limiting PALS and follicles, and some follicular dendritic cells (FDCs) in white pulp. The endothelial cells of venous sinuses in red pulp were also labeled by CMA and, if frozen sections were used, CMA also labeled the macrophages of the red pulp. Compared to CMA, the monoclonal antibody CD11, which can be used only in frozen sections, stained almost solely the fibrous (extracellular) component of the RM. Because CMA stains the reticulum cells in particular, it is better suited to visualize the stromal architecture of splenic white pulp than the monoclonal antibody. Because CMA can be applied to paraffin-embedded material, it is a particularly useful tool to study the splenic stromal architecture in archival material.

Serum ferritin iron in iron overload and liver damage: correlation to body iron stores and diagnostic relevance.

The iron content of serum ferritin has been determined in groups of patients with normal or increased iron stores by using a technique of ferritin immunoprecipitation followed by iron quantitation with atomic absorption spectroscopy. The results were correlated to individual liver iron concentrations, measured non-invasively by superconducting quantum interference device (SQUID) biomagnetometry. A close correlation between serum concentrations of ferritin protein and ferritin iron was found (r = 0.92) in all groups of patients. However, the correlation between ferritin iron concentration and individual liver iron concentration was poor in patients with hemochromatosis (r = 0.63) and patients with beta-thalassemia major (r = 0.57). The degree of ferritin iron saturation was about 5% in iron-loaded patients, which contrasts with results in two recent studies but confirms older observations. In patients with liver cell damage, the ferritin iron saturation in serum was significantly higher than that found in groups with iron overload disease, probably indicating the release of intracellular iron-rich ferritin into the blood. The monitoring of patients undergoing bone marrow transplantation indicated that the release of iron-rich and iron-poor ferritin occurred during phases of hepatocellular damage and inflammation, respectively. We find the benefits of serum ferritin iron measurement to be marginal in patients with iron overload disease.

Storage of iron in bone marrow plasma cells. Ultrastructural characterization, mobilization, and diagnostic significance.

The physiological site of iron storage in the human bone marrow is the macrophage (orthotopic iron store). Iron-storing plasma cells, as bone marrow indicators of iron overload, and/or chronic alcoholism represent a pathological (heterotopic) iron store. They were demonstrated by light and electron microscopy in 23 iron-overloaded patients: transfusional siderosis (n = 8), genetic haemochromatosis (GH; n = 11), iron-loading anaemias (n = 4) and in patients with bone marrow impairment due to chronic alcoholism (n = 6). The pattern of iron storage in bone marrow plasma cells was monitored during iron loading in patients receiving continuous transfusional therapy (n = 7) and also upon reversal of iron overload by repeated phlebotomies in GH (n = 9) and in iron-loading anaemias (n = 4). The first ultrastructural evidence of iron storage in plasma cells was the appearance of free ferritin molecules in the cytosol, thus indicating endogenous ferritin synthesis. Accumulation of iron proceeded with the additional formation of ferritin- and haemosiderin-containing lysosomes (siderosomes) in these cells. Lysosomal ferritin partially showed a paracrystalline array. The siderosomes originated from autophagocytosis of cytoplasmic areas containing free ferritin molecules. In addition, the formation of ferritin-containing vesicles in the proximity of the Golgi apparatus was observed. The heterotopic iron store of bone marrow plasma cells was less readily mobilizable by blood-letting than the orthotopic store of macrophages.

Pattern of iron storage in the rat heart following iron overloading with trimethylhexanoyl-ferrocene.

Female Wistar rats with slight iron deficiency anemia were kept on a diet containing 0.5% trimethylhexanoyl (TMH)-ferrocene for up to 79 weeks. In the state of iron deficiency, the heart was free of light-microscopically detectable iron. After 7 weeks of the TMH-ferrocene diet, the first iron-positive granules appeared in perivascular macrophages. Further oral administration caused a progression of iron deposition in these cells, visible in the form of a granular staining but also as a diffuse iron staining of the cytoplasm. Accordingly, at the electron-microscopical level, the iron was stored partly as free ferritin molecules in the cytosol, and partly in lysosomes in the form of ferritin and/or hemosiderin. After 11 weeks, further iron-positive cells with relatively small dark-blue granules were found in the vicinity of capillaries, which could be identified as fibrocytes by means of electron microscopy. In addition, slight iron deposition occurred in the endothelial cells of the cardiac capillaries, likewise mainly in the form of small, uniform siderosomes. The myocytes showed no product of Perls' Prussian blue reaction during the whole period of investigation. From the 11th week onwards, discrete ferritin molecules were detected electron microscopically within lysosomes of these cells. Their amount increased slowly with progression of the TMH-ferrocene feeding period. Free ferritin molecules could be observed in the cytosol of fibrocytes, endothelial cells and myocytes in only very slight concentrations, whilst they were more plentiful in macrophages. In hereditary hemochromatosis and posttransfusional siderosis, the iron is found predominantly in myocytes and appears to cause cell damage, whilst this is not the case in experimental iron overload in rats.

Chronic feeding of carbonyl-iron and TMH-ferrocene in rats. Comparison of two iron-overload models with different iron absorption.

1. The use of carbonyl-iron and (3,5,5-trimethylhexanoyl)-ferrocene (TMH-ferrocene) as a dietary iron-overload model was studied in rats using 59Fe-labelled compounds. 2. The intestinal absorption of carbonyl-iron but not from the TMH-ferrocene-iron was dependent upon the dosage and downregulated in iron-loaded rats. 3. In both models, and similar to hereditary haemochromatosis in humans, the storage of excess iron in the liver started in hepatocytes, whereas the range of iron-loading was strikingly different. 4. Because of the fast and progressive iron-loading, the TMH-ferrocene-model is the most encouraging animal model for experimental haemochromatosis.

Non-transferrin-bound-iron in serum and low-molecular-weight-iron in the liver of dietary iron-loaded rats.

1. The feeding of 0.5% (3,5,5-trimethylhexanoyl)ferrocene (TMH-ferrocene) in rats resulted in a severe and progressive liver siderosis (total liver iron, 30 mg/g liver wet weight, after 30 weeks). 2. High concentrations of an iron-rich ferritin (up to 250 mg/l) were detected in serum of heavily iron-loaded rats forming a large fraction of non-transferrin-bound-iron (5000 micrograms/dl in maximum). 3. Ferritin and not haemosiderin was the major iron storage protein in the liver. 4. The total liver iron concentration (from 0.4 to > 30 mg Fe/g wet wt) but not the cytosolic low-molecular-weight-iron fraction (from 0.5 to 2.5 microM) was extremely increased during iron-loading.

Iron overload of the liver by trimethylhexanoylferrocene in rats.

Iron-deficient female Wistar rats were fed a diet, which contained 0.5% trimethylhexanoylferrocene, over a 56-week period. This dietary iron loading resulted in a progressive siderosis and enlargement of the liver with a maximum iron content of 947.0 +/- 148.0 mg (vs. 0.07 +/- 0.04 mg in iron deficiency) and a maximum organ weight of 39.4 +/- 6.6 g (vs. 6.9 +/- 1.4 g in iron-deficient control rats). Up to 43 weeks, whole liver iron rose by increase in iron concentration (max. 28.0 +/- 6.1 mg/g wet weight, w.w.) as well as by enlargement of the organ. Afterwards whole liver iron increased solely by ongoing hepatomegaly. At the commencement of iron loading, stainable iron was almost exclusively stored by hepatocytes equally throughout all areas of the liver lobule. Later, the distribution of iron-loaded hepatocytes became strikingly periportal, and, in addition, Kupffer cells as well as sinus-lining endothelia began to store iron. Animals with a liver iron concentration of more than 10.4 +/- 0.75 mg/g w.w. showed no further increase in ferritin and haemosiderin within hepatocytes. Iron-burdened Kupffer cells/macrophages, however, accumulated permanently, hereby forming intrasinusoidal and portal siderotic nodules and areas. First signs of liver damage such as necrosis of single hepatocytes and mild fibrosis began at a liver iron concentration of 14.7 +/- 1.4 mg/g w.w. With advancement of iron loading, focal necrosis of hepatocytes and iron-burdened macrophages took place, and significant perisinusoidal as well as portal fibrosis developed. Cirrhosis, however, the final stage of impairment in iron overload of the liver in humans, could not be induced in this animal model up to now.

Transport of siderotic Kupffer cells to the lung and bronchial excretion of iron in experimental iron-overload.

In 3,5,5-trimethylhexanoylferrocene-induced iron overload of rats, three different types of iron-loaded macrophages and derivatives thereof were found in the lungs. On the basis of their localization and of their pattern of iron load it was possible to distinguish: (1) Resident macrophages, showing an alveolar localization and a moderate iron content represented by lysosomal ferritin and haemosiderin. (2) Liver-derived macrophages and giant cells, as well as fragments of them. They showed an exclusive localization in capillaries and alveolar septa, and high concentrations of free ferritin molecules in addition to polymorphous ferritin- and haemosiderin-containing siderosomes. (3) Monocyte-derived intravascular pulmonary macrophages. Initially, they contained iron only as lysosomal aggregates of ferritin and haemosiderin, as a result of phagocytosis of liver-derived macrophageal cell fragments. Later in iron overload, they also showed free ferritin molecules in the cytosol and fused intrapulmonarily to giant cells. The resident as well as the liver-derived siderotic pulmonary macrophages provide a way for iron excretion through the airways.

Iron overload of the bone marrow by trimethylhexanoyl-ferrocene in rats.

Iron-deficient female Wistar rats were fed a diet which contained 0.5% 3,5,5-trimethylhexanoyl (TMH)-ferrocene over a 57-week period. The state of iron deficiency was characterized by means of the absence of stainable iron in the bone marrow. After the first days on the iron-enriched diet, ferritin-containing siderosomes were found, in numerous erythroblasts up to orthochromatic normoblasts and in reticulocytes, i.e. the dispensed iron was used for haemoglobin synthesis. After 1 week the first macrophages showed a positive Perls' Prussian blue reaction. In the cytoplasm they stored the iron in the form of free ferritin molecules and lysosomally as aggregated ferritin and/or haemosiderin. The iron loading of the macrophages increased in both of the storage qualities proportionally with duration of the feeding period and reached a maximum after 38 weeks. Final stages showed extremely iron-loaded macrophages with high concentrations of free ferritin molecules and large siderosomes, partially flowing together to still greater units. Iron deposits within endothelial cells of bone marrow sinusoids can be observed for the first time after 4 weeks. In these cells the iron is stored as ferritin in siderosomes of relatively small and uniform size; free ferritin molecules in the cytosol were of only slight concentration. The TMH-ferrocene model of iron overload shows in the bone marrow: (1) an unimpeded utilization of the iron component for erythropoiesis, (2) development of excessive iron overload of the bone marrow in macrophages and endothelial cells of sinusoids and (3) a pattern of distribution of iron as seen in secondary haemochromatosis.

Absence of macrophage and presence of plasmacellular iron storage in the terminal duodenum of patients with hereditary haemochromatosis.

Biopsy specimens of the terminal duodenum obtained from 11 patients with hereditary haemochromatosis were examined by light and electron microscopy. Stainable iron was found in the lamina propria of the terminal duodenum in only 4 patients, all of whom were in an advanced stage of the disease. The iron was localized in the basal parts of the villi, sparing their tips, and between the crypts of Lieberkühn. The iron-storing cells could be identified as plasma cells, in which ferritin and haemosiderin were localized within lysosomes and ferritin molecules scattered in the cell sap. There was no storage of iron in macrophages. These observations demonstrate the impaired iron-storing capacity of macrophages in hereditary haemochromatosis, which may be related to the increased iron absorption in this iron storage disease.

The diagnostic value of bone marrow iron.

The light and electronmicroscopic representation of non-haemiron in the bone-marrow provides the unique opportunity of extensively evaluating the iron metabolism. In the bone-marrow, macrophages represent the physiological place of iron storage. The iron in the cytoplasma is stored in them in the form of free ferritin molecules and lysomally as aggregated ferritin and/or haemosiderin in siderosomes. In an equal iron balance and unimpaired internal iron exchange only erythroblasts (sideroblasts) and erythrocytes (siderocytes) of the bone-marrow besides macrophages possess siderosomes. In addition to this physiological or orthotopic iron storage a heterotopic iron storage can be observed under pathological conditions, particularly with iron overloading of the organism, in the endothelial cells of sinusoids and plasma cells. In detail, the patterns of iron storage in the bone-marrow are described in the different stages of iron deficiency, disturbance of iron utilization in chronically inflammatory processes or tumour diseases, condition after intravenous iron administration, transfusion siderosis, hereditary haemochromatosis and sideroblastic anaemia.

[Differences in the pattern of iron accumulation in primary and secondary hemochromatosis. Diagnostic importance and clinical consequences]. / Unterschiede im Muster der Eisenspeicherung bei primärer und sekundärer Hämochromatose. Ihre diagnostische Bedeutung und klinische Konsequenz.

In secondary haemochromatosis up to fourfold higher amounts of iron are tolerated in the organism than in primary (hereditary) haemochromatosis. This is connected with the marked iron storage of macrophages in secondary iron overloading, which is relatively without any dangers. In primary haemochromatosis, however, a relative insufficiency of storage of extrahepatic macrophages can be observed for iron, a fact which favours a premature parenchymatous iron storage leading to organ lesions. Because of the discrepant behaviour of macrophages characteristic, diagnostically relevant differences will occur in the pattern of iron storage in the bone-marrow, spleen and small intestine between primary and secondary haemochromatosis.

Amsacrine, cytarabine and thioguanine (AAT) versus daunorubicin, cytarabine, thioguanine (DAT) in adults with untreated acute non-lymphoblastic leukemia (ANLL). Austrian-German results.

69 patients (median age 53 years, 19-79 years old) with untreated acute non-lymphoblastic leukemia (ANLL) were randomized to receive either a regimen of amsacrine, cytarabine, thioguanine (AAT) or daunorubicin, cytarabine, thioguanine (DAT). AAT consisted of amsacrine 200 mg/m2/day x 5, thioguanine 100 mg/m2/12 h p.o. x 10; DAT was daunorubicin 50 mg/m2/day x 3, cytarabine 200 mg/m2/day x 5, thioguanine 100 mg/m2/12 h p.o. x 10. After one or two induction courses the patients subsequently received 2 consolidation courses. 17 patients were not assessable for response to therapy due to exitus during induction treatment. Complete remission could be obtained in 14/24 (58%) of DAT patients respectively. Patients less than 60 years of age achieved CR in 63% (AAT) vs 65% (DAT), whereas patients greater than or equal to 60 years obtained a CR in 50% (AAT) vs 13% (DAT). Toxicity appears not to be increased significantly with amsacrine. These data indicate that amsacrine could replace daunorubicin in remission induction regimens of ANLL containing cytosin arabinoside and thioguanine without decreasing the response rate.

[Hairy cell leukemia. 2d report on the clinical course, morphology and therapy of 27 patients]. / Die Haarzell-Leukämie. Zweiter Bericht zur Klinik, Morphologie und Therapie bei nunmehr 27 Patienten.

The course of hairy cell leukaemia was observed in 27 patients for a maximum of 97 months. Splenectomy had been performed in 17 patients and improved the haematological situation impressively in most cases. Amongst patients with splenectomy ten are alive with 8 to 88 months postoperatively. In five of them disease manifesting as isolated leucocytosis, deterioration of the overall haematological situation or as intraabdominal lymphomatous growth could be treated successfully. Treatment consisted of leucapheresis, low-dose long-term therapy with chlorambucil, administration of doxorubicin (adriamycin) or a combination of cytostatics containing doxorubicin as well as abdominal localized or overall irradiation.

Iron storage in macrophages and endothelial cells. Histochemistry, ultrastructure, and clinical significance.

1 hour after i. v. infusion of colloidal iron in iron deficient subjects uniform phagosomal iron granules were observed in macrophages and endothelial cells of several organs. 7 to 10 days later transformation into ferritin coould be visualized in macrophages only. Now, these cells showed diffuse iron staining of the cytoplasm due to dispersed ferritin molecules. Polymorphous lysosomes contained densely packed particles from still unchanged ferric hydroxide to paracristalline ferritin. The macrophageal iron was mobilizable in few days to several weeks. The univorm lysosomal iron granules of endothelial cells disappeared after 1 to 2 years. Endothelial iron siderosis without previous i. v. iron application was a frequent finding in pernicious anaemia and iron overload of diverse origin.