Preliminary observation of blood cells and hematopoietic organs in Lutjanus herenbergi and Lutjanus flaviflammus

The morphology of differentiated and differentiating cells of the red and white series in Lutjanus herenbergi and in Lutjanus flaviflammus is described. Early stages of red and white blood cells may be found only in smears of hemopoietic organs. Polychromatic erythroblasts, myelocytes and lymphoblasts may also occasionally be found in blood smears. Mature blood cells may be found both in blood smears and in hemopoietic organs. Differential white cell counts seem to demonstrate that the granulocytic series elements are the most common leukocytes in blood smears. Almost all granulocytes may be classified in the first three Arneth classes. An analysis of hemopoietic organs in these species was also performed. It was found that the only organs carrying on a hemopoietic function are the kidney and the spleen. The kidney is essentially a site of granulocytic differentiation while the spleen is a lymphopoietic organ. An erythropoietic activity may generally be observed in the kidney although weak erythropoietic activity may at times be found in the spleen.     

The effect of toluene on the hematopoietic system in newt Triturus cristatus

A macrocytic hypocromic anemia was observed in newts after toluene inhalation, with 2 concentrations, for 6 weeks. Anemia resulted associated with the used dose of toluene. Erythroblast counts, performed on blood smears and on spleen and heart imprints, showed an erythropoietic stimulus during the first weeks of treatment followed by a depressed erythrostimulating action. Differential count of erythroblasts indicated a slow maturation induced by toluene on erythroblasts. An aplasia of the spleen was suggested on the basis of the results from 6 week-treated animals. A reduction in white blood cell count, associated with increased neutrophils and lymphocytopenia, occurred only in the animals treated with the higher concentration of toluene, after 5 and 6 weeks of treatment. A decrease of phagocytic activity of neutrophils, obtained with the in vitro assays, appeared the most relevant finding at the level of lekocyte compartment.     

Effect of bleeding on irradiation-induced erythropoiesis in the spleen of AKR mice

The effect of erythropoietin, increased by bleeding, on the erythropoiesis induced by irradiation in the spleen of AKR mice, has been studied. The following parameters were measured to quantify the erythropoietic activity: the number and size of hematopoietic nodules (colonies) and proerythroblasts in the spleen, the spleen, blood and red-cell 59Fe uptake and the hematocrit and reticulocytes in the blood. Under erythropoietic stimulus an increase in the number and size of colonies was observed and these colonies were observed sooner because of their more rapid growth. The proerythroblasts in the spleen appeared earlier, and there were increases in the spleen, blood and red-cell 59Fe uptake and in the hematocrit and reticulocytes in the blood.     

A high-affinity,low-capacity receptor for estradiol in normal and anemic mouse spleen cytosols

A high-affinity, low-capacity receptor activity for 17 β-estradiol has been identified in cytosols of mouse spleen, normal or erythropoietic. It appears to be a protein which sediments at 5S in high-salt gradients and with a peak at 4S and a shoulder at 8-10S in low-salt gradients. In addition to 17 β-estradiol, only 17 α-estradiol and 5(10)-estren-3 α, 17 β-diol competed successfully with the steroid ligand. A K_d of 1.5 × 10^?9 M and 4.1 fmoles/mg protein for the number of binding sites were calculated for the receptor activity of early erythropoietic spleen cytosols.     

Effect of spleen congestion and decongestion on newt blood

Experiments on the newt Triturus cristatus carnifex have shown that the spleen of specimens, either anaesthetized with chlorobutanol or in a normal condition, stores red blood cells when the animal is well oxygenated and releases these into circulation under conditions of hypoxia. The extreme limits of congestion and decongestion, commonly encountered in nature, can be obtained in the laboratory by exposing the animals to the air or by immersing them in still water. During the shift from a congested to decongested state, the spleen is reduced to less than one-fifth of its weight, while the erythrocyte concentration and correlated parameters in the blood stream increase by more than 60%. Splenic regulation of the circulating erythrocyte concentration compensates not only for variations in oxygen supply linked to environment, it may also compensate for the cyclical variations in red cell production of this amphibian, whose erythropoietic tissue activity is intermittent and subject to seasonal variations.     

The cellular composition of the blood and haematopoietic organs of turbot Scophthalmus maximus L.

The cellular composition of the blood, anterior kidney, spleen and thymus of turbot Scophrhalmus maximus L., aged 1 + was determined. Ninety-four per cent of blood cells belonged to the erythrocyte lineage of which 82% were mature erythrocytes. The leucocytes, which represented 4.5% of the blood cells, were mainly lymphocytes (50%). The presence of crythroblasts in the anterior kidney and the spleen demonstrated an erythropoietic activity in both organs. However, this activity appeared to be prevalent in the spleen which also appeared to act as a storage zone for erythrocytes and as the centre point for thrombopoiesis. Although 96% of the anterior kidney cells were leucocytes, the number of white cells per gram of organ was higher in the spleen.     

A mathematical model of erythropoiesis in mice and rats. Part 4: Differences between bone marrow and spleen

In a preceding analysis we hypothesized that the most important parameter controlled by erythropoietic regulation in vivo is the degree of amplification (number of cell divisions) in the CFU-E and erythroblast cell stages. It was concluded that erythropoietic amplification in vivo is controlled according to a sigmoidal dose-response relationship with respect to the control parameter which is the haematocrit (or haemoglobin concentration). Here, this hypothesis is extended to include the differences in murine bone marrow and splenic erythropoiesis that are described and quantified by different dose-response relationships. Comparing several sets of experimental data with mathematical model simulations, this approach leads to the following conclusions: (i) in the unperturbed normal steady state at least one extra erythropoietic cell division takes place in the spleen compared with the bone marrow; (ii) a strong erythropoietic stimulus, such as severe bleeding or hypoxia, can induce five to six additional cell divisions in the spleen but only two to three additional divisions in the bone marrow; this results in a considerable increase in the spleen's contribution to erythropoiesis from about 10% in normal animals to over 40% during strong stimulation; (iii) under erythropoietic suppression, such as red cell transfusion, a similar number of cell divisions is skipped in both organs and the splenic contribution to erythropoiesis remains unchanged. In conclusion, the concept that bone marrow and spleen microenvironments differ in the dose-response relationship for erythropoietic regulation provides an explanation for the changing contribution of splenic murine erythropoiesis following a variety of experimental treatments.     

A mathematical model of erythropoiesis in mice and rats. Part 4: Differences between bone marrow and spleen

Abstract. In a preceding analysis we hypothesized that the most important parameter controlled by erythropoietic regulation in vivo is the degree of amplification (number of cell divisions) in the CFU-E and erythroblast cell stages. It was concluded that erythropoetic amplification in vivo is controlled according to a sigmoidal dose-response relationship with respect to the control parameter which is the haematocrit (or haemoglobin concentration). Here, this hypothesis is extended to include the differences in murine bone marrow and splenic erythropoiesis that are described and quantified by different dose-response relationships. Comparing several sets of experimental data with mathematical model simulations, this approach leads to the following conclusions: (i) in the unperturbed normal steady state at least one extra erythropoietic cell division takes place in the spleen compared with the bone marrow; (ii) a strong erythropoietic stimulus, such as severe bleeding or hypoxia, can induce five to six additional cell divisions in the spleen but only two to three additional divisions in the bone marrow; this results in a considerable increase in the spleen's contribution to erythropoiesis from about 10% in normal animals to over 40% during strong stimulation; (iii) under erythropoietic suppression, such as red cell transfusion, a similar number of cell divisions is skipped in both organs and the splenic contribution to erythropoiesis remains unchanged. In conclusion, the concept that bone marrow and spleen microenvironments differ in the dose-response relationship for erythropoietic regulation provides an explanation for the changing contribution of splenic murine erythropoiesis following a variety of experimental treatments.     

Antibody formation and B-cell migration from bone marrow to spleen in mice under conditions of stimulation and suppression of erythropoiesis]

The effect of erythropoietic stimulation and suppression on the production of antibody-forming cells (AFC) in the spleen and on the B-cell migration from the bone marrow to the spleen was investigated in the CBA mice. Erythropoiesis stimulation proved to sharply increase the AFC count in the spleen and the B-cell migration from the bone marrow to the spleen 1 and 4 days after the bleeding. Erythropoiesis suppression resulted in a slight increase of the AFC count in the spleen 4 and 7 days after the transfusion of syngeneic red blood cells. However, the erythropoietic suppression inhibited the B-cell migration from the bone marrow to the spleen. Possible mechanisms of the effect of the erythropoietic stimulation and suppression on the antibody production are discussed.     

Periodic changes in the organs involved in the erythropoiesis of anemic newts

In Triturus cristatus carnifex (Laurenti) newts rendered totally anemic by treatment with acetylphenylhydrazine (APH) diluted in their tank water (25 mg/liter for 48 hours, with four changes) the recovery of erythron occurs through periodic cycles of mitotic activity in the erythropoietic tissue. These cycles determine a marked increase in blood erythrocyte concentration at regular intervals of about 1 month. The consequence of this trend is the alternation of ferritin and hemosiderin accumulation phases during periods of stasis with iron mobilization phases during periods of erythropoietic activity, which is particularly evident in the Kupffer cells of the liver. Iron mobilization and erythropoietic activity are strictly related to the periodic hypertrophy of some Bowman's capsule cells in the renal corpuscle, which were previously denominated "lactate sensitive cells" (LSC). The histochemistry, location, and behavior of LSC indicate that they are probably the site of erythropoietin production in the newt.     

An erythropoietic stimulating factor similar to erythropoietin released by macrophages after treatment with silica

An erythropoietic stimulating factor (ESF) can be detected in the supernatant from fetal liver and adult bone marrow and spleen cells when preincubated with the macrophage-specific cytotoxic agent, silica. Stimulation is observed in 12-day fetal liver CFU-E cultures in the absence of added erythropoietin (Ep). The concentration of ESF in the supernatant added to CFU-E cultures is dependent on the preincubated cell dose and the volume added. The stimulating activity is abolished when mice are hypertransfused and increased above normal values when mice are bled. A concentrated silica-treated spleen supernatant was able to stimulate erythropoiesis in the polycythemic mouse bioassay. It is concluded that the ESF is similar, if not identical, to Ep.     

Microcythemia from anemic hypoxia and normal erythropoiesis in the newt

Specimens of the newt, Triturus cristatus carnifex (Laurenti), rendered totally anemic, restore erythron by cyclic waves of erythropoietic activity that alternate with intervals of stasis. Hemolysis is obtained by administering 25 mg/liter of acetylphenylhydrazine in the breeding water for 36 h. The first cycle of erythropoietic activity produces microcytes, which have completely differentiated by 8 weeks after treatment. However, if the animals are raised in a hyperbaric chamber at a pressure of 1.5 atmospheres, in order to compensate for hypoxia, normocytes are produced. In both cases the hematocrit and hematic concentration of hemoglobin reach analogous values, so microcythemia appears to be the only effect of hypoxia. The hemoglobin, hematocrit values, and normocyte counts in hyperbaric animals are about one-half those of the controls newts. These data, together with those on the life span of red blood cells (RBC) and time span between two successive erythropoietic cycles (2 months and 1 month, respectively), indicate that the newts normally keep only two sets (one new, one old) of RBC in circulation, whose approximate parameters can be defined as RBC count: 60,000/mm3, hematocrit: 17%, and hemoglobin: 5.4 g/100 ml.     

Sites and trend of erythropoiesis in anemic, normal, and splenectomized newts

Newts, Triturus cristatus carnifex (Laurenti), were anesthetized by submersion in 2% chlorbutol in tap water for 15 min, splenectomized and then rendered totally anemic two months later by treatment with acetylphenylhydrazine (APH) diluted in their tanks (25 mg/liter for 36 h, changing the solution every 12 h). In the 14 weeks following hemolysis, erythron restoration occurred with the same intermittence as it did in whole animals rendered anemic by APH treatment: Beginning the second week the red blood cell count progressively increases for about one month, followed by a period of stasis which lasts about three weeks, then by a new increase, and then by a final period of stasis. Histological examination shows that erythropoietic activity occurs partly in the circulating blood and partly in erythroblasts nestled in the crypts between the muscular trabeculae of the ventricle as well as in the atrial walls. These cells, which are not part of the freely circulating elements in the blood stream, become very abundant in both whole and splenectomized anemic newts but are also present in normal animals. Newts, thus, have three sites for erythropoiesis: the spleen, the blood stream, and the heart. The other components compensate for the elimination of the spleen without determining any lack of, or delay in, erythropoietic response.     

Endothelial cells create a hematopoietic inductive microenvironment preferential to erythropoiesis in the mouse spleen

The spleen is an erythropoietic organ in mouse. To reconstruct a microenvironment essential for erythropoiesis in vitro, the stroma (MSS31) cell line had been established from a newborn mouse spleens. MSS31 cells exhibited properties of endothelial cells: (a) the cells showed the activity to uptake acetylated low-density lipoprotein (Ac-LDL) and (b) the cells can form a capillarylike structure by a phenotypic modulation in collagen matrices. MSS31 cells selectively supported the proliferation and differentiation of the erythroid progenitor cells by direct cell-to-cell contact in a semisolid medium in the presence of erythropoietin. These layers also supported erythrocyte maturation and enucleation of erythroblasts. This suggests that spleen endothelial cells are a new type of stromal cell with erythropoietic stimulation activity and may have a critical function in the hemopoietic inductive microenvironment of the mouse spleen.     

In inherited porphyrias, lead intoxication is a toxogenetic disorder

1. delta-Aminolevulinic acid dehydratase (ALA-D), blood lead and several enzymes and metabolites of the heme biosynthetic pathway were measured in a number of symptomatic porphyric patients, 22 with acute intermittent porphyria, three with hereditary hepatic coproporphyria, 10 with hereditary porphyria cutanea tarda, two with erythropoietic protoporphyria and two with congenital erythropoietic porphyria and in 84 lead intoxicated persons. 2. In the 39 individuals suffering from the inherited porphyrias and in 32 lead poisoned patients with a 30-50% reduced deaminase, blood lead content was not sufficiently increased (average 28 micrograms%) to account for the greatly decreased activity of ALA-D (average 36% of controls). 3. After a relatively trifling lead exposure they developed the signs of acute lead intoxication. 4. A second group of lead intoxicated patients showing low ALA-D activity and corresponding high concentration of lead in blood, exhibited no other physiologic deviation in the enzymes and metabolites of porphyrin biosynthesis. 5. Individuals with inherited porphyrias are ultrasensitive to low level lead exposure and that lead would also act as a triggering factor. In these patients, lead intoxication can be considered a toxogenetic disorder. 6. An inversely linear correlation between ALA-D activity and blood lead content was obtained for both groups of lead intoxicated patients, however, a different constant (k) for each was obtained, which we have taken as a measure of lead toxogeneticity: k = 10 +/- 1 for lead intoxicated individuals with otherwise normal heme metabolism and k = 5 +/- 0.5 for lead intoxicated symptomatic porphyric patients. 7. Determination of erythrocytic ALA-D, besides blood lead, will be a valuable indicator for preventive medical care for these patients, when they are expected to be exposed to lead either environmentally or in their professional life.     

Evaluation of the marrow culture on the macrophage layer covering intraperitoneally implanted membrane as an assay for hemopoietic progenitor cells

When cellulose acetate membranes are implanted into abdominal cavity of mice they turn into a foreign body overgrown with macrophages. Such macrophage layer has been shown by other authors to be able to support the growth of hemopoietic colonies formed by intraperitoneally injected hemopoietic cells. This study confirms and extends this observation by showing that both granulopoietic and erythropoietic colonies may be observed. The number of colonies grown is in linear correlation with that of injected hemopoietic cells. The frequency of erythropoietic colonies was greatly enhanced by blood letting of the host mice. Colony forming cells were most numerous in the bone marrow then in the spleen and peripheral blood and hardly in the thymus. Prior irradiation of the host mice was essential for obtaining colony growth and the optimal dose was determined to be 6.0 Gy. This technique opens the way to studies into hemopoietic progenitor cells for laboratories having no sophisticated tissue culture equipment and where necessary reagents are easily available.     

The Wavy Erythropoiesis of Developing Chick Embryos. Isolation of Each Wave by a Differential Lysis and Identification of the Constituent Erythroid Types

Erythroid carbonic anhydrase (CA) activity of chick embryos from the third day of incubation to the egg hatching has been determined. Five minor activity peaks with maxima at 3, 6, 9, 15 and 17 days of development and a major one with maximum at 19 days have been found. The correlation between the peak distribution and the timing of release into the blood stream of waves of newly produced erythroid cells has been demonstrated on the basis of the following observations: 1) a linear correlation exists between red cell maturation and increase of CA activity; 2) chick red cells undergo lysis in the "Ørskov" medium when their CA activity exceeds a threshold value (23±3 Units/10⁹ red cells); and 3) the lysis kinetics of red cells in the Ørskov medium is proportional to their CA content. We have thus been able to distinguish the immature erythroid forms from the mature ones on the basis of their behaviour in the Ørskov medium. In the blood of developing chick embryos, we have found waves of newly produced red cells at about 2, 4, 7, 10, 16 and 18 days of development.
The same experimental criteria allowed us to detect the waves of red cell production in the erythropoietic organs. One wave has been detected in the blood islands at about 2 days; four waves in the yolk sac at about 5, 6, 11 and 15 days; two waves in the spleen at about 18 and 20 days; two waves in the bone marrow at about 19 days of incubation and 1 day after hatching.
Primitive erythroid cells are produced in the first two waves: that of blood islands at 2 days and that of yolk sac at 5 days. Definitive red cells are produced in the other waves with the exception of the second wave of spleen and of the second wave of bone marrow, which are constituted by red cells of adult type.     

Deoxyuridine triphosphate nucleotidohydrolase activity and its correlation with multiplication of erythroid cells in rat spleen

The administration of phenylhydrazine to rats brought about a marked increase in the dUTPase activity in the cytosol fractions of spleen and red blood cells; the activity began to increase with a two-day lag and reached the maximum at the 5th or 6th day of the phenylhydrazine treatment (13 and 5 times the control values in total activity in the spleen and red blood cells, respectively), and then the activity decreased. The activities of thymidine kinase and sigma-aminolevulinate synthase in the spleen and red blood cells also changed in parallel with that of dUTPase. The increases of these activities were suppressed completely by methotrexate, an inhibitor of DNA synthesis. The time courses of the enzyme activity changes in the red blood cells, however, were slightly behind those in the spleen. Thus, a close correlation was assumed between the dUTPase activity and the multiplication of erythroid cells in rat spleen.