The determination of the developmental stages in the hamster using erythroid cell development.

A technique was developed for the determination of developmental stages by measuring the electronically determined volume of fetal blood cells. The size shifts of the nucleated and nonnucleated cell populations as well as the release of liver reticulocytes that occurs between the twelfth and thirteenth days provided hematological correlates of gestational development.     

THE SEPARATION OF DIFFERENT CELL CLASSES FROM LYMPHOID ORGANS : III. The Purification of Erythroid Cells by pH-Induced Density Changes

1. Mammalian erythrocytes swell as the pH of the isotonic suspending medium is lowered, as a direct consequence of the specialized permeability properties of the erythrocyte membrane. Lymphocytes and granulocytes from a variety of sources did not exhibit this property. 2. The behaviour of mouse bone marrow erythroid cells at various stages of differentiation was studied by using a change in buoyant density with pH as an index of swelling. The ability to swell with a pH drop was acquired while the cell was still nucleated. All non-nucleated cells showed swelling. Most small erythroblasts shared this property, whereas most large erythroblasts did not. 3. The density shift with pH was used to provide a purification scheme specific for erythroid cells. The bone marrow cells were first centrifuged to equilibrium in an isotonic albumin density gradient at neutral pH. Regions of the gradient containing the erythroid cells were collected, and the cells were recovered and redistributed in an albumin gradient at acid pH. The erythroid cells showed a specific density shift which removed them from contaminants. Preparations containing 90–97% erythroblasts were obtained by this technique. 4. Differentiation within the erythroid series was accompanied by a general increase in cell buoyant density at neutral pH. This density increase may have been a discontinuous process, since erythroid cells appeared to form a number of density peaks. 5. The pH shift technique, in association with established density distribution and sedimentation velocity procedures, provides a range of cell separation techniques for biological or biochemical studies of erythroid cell differentiation in the complex cell mixtures in bone marrow or spleen.     

Age dependent change in size distribution of blood cells in fetal and young mice

The mean corpuscular volume (MCV) and the size distribution of circulating blood cells were determined in the fetal mice of C3H/He strain by using a new electric cell size analyser, Coulter Channelyzer C-256. On the 12th day of gestation, the volume of circulating blood cells was distributed between approximately 240-820 fl (mode at 470 fl), and the MCV was 534.9 +/- 30.1 fl, i. e., ten to eleven times that of adult one. On the 14th day, two types of cell population were observed; one with smaller cell volume and another with larger one corresponded to that of the blood cells on day 12. Therefore, two peaks were observed to be at 140 and 501 fl in the size distribution curve. The cell population with large volume observed on day 12-14 had been almost disappeared by the 16th day of gestation, and the small blood cells became dominant. The MCV of blood cells was then decreased with the development of fetus, from 188.2 +/- 19.3 fl on day 16, to 135.1 +/- 7.3 fl on day 18, and 117.5 +/- 7.2 fl on day 20. The size of blood cells continued to decrease gradually after birth, and became adult range by 8 weeks after birth. The MCV values of the blood cells were 120.9 +/- 8.6 fl, 87.5 +/- 6.2 fl, and 48.7 +/- 0.8 fl for the newborns of 1 day and 7 days old, and the adult mice, respectively. White blood cells were not separated from the blood samples in this study. However, the size distribution and MCV presented above were appeared to be related essentially to the red blood cells, since the number of white blood cells are negligible small compared with that of the red cells.     

Transferrin receptors and iron uptake during erythroid cell development

Experiments were performed to determine the level of transferrin receptors and rate of transferrin-bound iron uptake by various immature erythroid cell populations. Developing erythroid cells from the rat and mouse foetal liver at various stages of gestation were studied. In addition Friend leukaemic cells grown in culture were examined. The transferrin receptor level of Friend cells was similar to that of erythroid cells from the mouse foetal liver. During erythroid cell development the transferrin receptor level increased from about 300,000 per cell at the early normoblast stage to reach a maximum of about 8000,000 per cell on intermediate normoblasts. Further maturation of intermediate normoblasts was accompanied by a decline in the number of transferrin receptors, reaching a level of 105,000 in the circulating reticulocyte. The rate of iron uptake from transferrin during erythroid cell development was found to correlate closely with the number of transferrin receptors. In each of the immature erythroid cell populations studied the rate of iron uptake was about 36 iron atoms per receptor per hour. These results indicate that the level of transferrin receptors may be the major factor which determines the rate of iron uptake during erythroid cell development.     

Microenvironment created by stromal cells is essential for a rapid expansion of erythroid cells in mouse fetal liver

Mouse stromal cell lines (FLS lines), established from the livers of 13-day gestation mouse fetus, supported the proliferation and differentiation of the erythroid progenitor cells from mouse fetal livers and bone marrow in a semisolid medium in the presence of erythropoietin. A large erythroid colony of over 1000 benzidine-positive erythroid cells was developed from a single erythroid progenitor cell on the FLS cell layer after 4 days of culture. When in close contact with the layer, the erythroid progenitor cells divided rapidly with an average generation time of 9.6 h and mature erythroid cells, including enucleated erythrocytes, were produced. The present studies demonstrate that the microenvironment created by the stromal cells can support the rapid expansion of erythropoietic cell population in the fetal liver of mice.     

Development of the mouse hematopoietic system. II. Estimation of spleen and liver "stem" cell number

Colony-forming cells (CFU), which have the general properties of hemopoietic “stem” cells, appear to be augmented in the mouse fetal liver from 12–18 days gestation and then decrease in the newborn. This finding suggests that few, if any, hemopoietic “stem” cells remain in the adult liver, an organ which appears to be unable to function erythropoietically, even at times of severe crises. In the spleen, and active adult as well as embryonic hematopoietic organ, the total number of CFU increases from 18 days gestation until at least 7 days after birth. Spleen and liver CFU augmentation seems to occur in cojunction with an analogous expansion of non-hematopoietic cells. The data suggests, in fact, that while there is an increase in the total number of liver CFU, there is also a dilution of liver CFU in the total cell population at successively later gestational ages.     

Cell size distribution in the thymus as a function of age

Although it is well known that thymus function changes with age, it is not known whether these changes are associated with specific thymocyte populations. Since one criterion of specificity is cell size, we studied the size distribution of thymocytes from mice 0.5 days to 30.5 months of age. Body weight, thymus weight, and thymocyte yield were also measured. The mean cell volume of thymocytes from 8.5 to 13 week old mice was 326 μ³, with two detectable subpopulations. Mean thymocyte size was found to change with age. During the first postnatal week, the mean cell volume of the whole thymocyte population increased from 200 to 350 μ³, and the percentage of large cells increased greatly and constituted 90% of the whole population at four days of age. A rather slow decline in mean cell volume with some fluctuation occurred throughout the remaining life span, and at 30.5 months the mean had dropped to about 190 μ³. We suggest on the basis of these data that large thymocytes are involved in the contribution of the thymus to early postnatal development of the immune system and that the age-related functional capacity of the thymus is related to the size of the thymocyte population.     

LK sheep reticulocytosis: effect of anti-L on K influx and in vitro maturation

After massive hemorrhage, adult sheep with genotypically low potassium (LK) red cells temporarily produce high potassium (HK) cells with ouabain-sensitive K+ pump fluxes equivalent to mature HK red cells. In light of recent reports of different red cell volume populations accompanying the HK-LK transition also occurring in newborn LK sheep and the unresolved controversy over the effect of anti-L on K+ transport in these immature red cells, we have reexamined the K+ transport changes and the effect of anti-L in the newly formed HK cells at various times after anemic stress and under in vitro conditions. We found that approximately 7 d after bleeding, maximum reticulocytosis occurred in the peripheral blood. After separation by density centrifugation, the top 10% cell fraction contained 100% reticulocytes, with a mean cell volume 2.5 times larger than that of mature erythrocytes. These immature red cells were of HK type, and their K+ pump and leak fluxes were 30 and 10 times higher, respectively, than those found in mature LK cells. The new cells may possess HK- and LK- type pumps because K+ pump influx was significantly stimulated by anti- L. When separated by density centrifugation on days 9, 17, and 23 after bleeding, some of the cells apparently maintained their large size while gaining higher density. Large cells from day 9, kept in vitro for 22 h, showed anti-L-sensitive K+ pump and leak fluxes that declined within hours, paralleling the behavior of these cells in vivo, whereas cellular K+ levels changed much less. It is concluded that the newly formed red cells may belong to a stress-induced macrocytic cell population that does not acquire all of the characteristics of adult LK cells.     

ALTERATIONS IN POLYRIBOSOMES DURING ERYTHROID CELL MATURATION

This communication presents a morphological study of the changes in ribosome content and organization which occur during the maturation of erythroid cells of the phenylhydrazine-treated rabbit. Electron micrographs of thin sectioned nucleated and non-nucleated erythroid cells have been subjected to a quantitative analysis of the distribution of ribosomes as polyribosomes of various sizes and as single ribosomes. The ribosomes of nucleated erythroid cells of marrow are virtually all arranged in the polyribosome configuration consisting of clusters of 2 to 6 individual ribosomes. These cells are the most active in the erythroid series in protein biosynthesis. During maturation to the non-nucleated reticulocyte stage, found in the circulating blood, there is a decrease in protein synthesizing capacity, a fall in total ribosome content, and, more significantly, a decrease in the number and size of polyribosomes. Maturation to the ribosome-free erythrocyte, either under in vitro or in vivo conditions, entails a further decrease in protein synthesis which correlates with a progressive disaggregation of the biosynthetically active polyribosomes into smaller clusters and inactive single ribosomes. Possible models which may account for the stability of the polyribosome and for the mechanism of polyribosome dissociation are discussed.     

Proliferation of Pasteurella pneumotropica at oestrus in the vagina of rats

Using a colony of Wistar-Imamichi rats contaminated with P. pneumotropica, the vaginal microflora was qualitatively and quantitatively investigated by swabbing. P. pneumotropica was the most dominant organism in the majority of rats examined. The population of P. pneumotropica and indigenous bacteria increased significantly higher at oestrus than in other oestrous stages. By the vaginal flushing technique changes in the population of P. pneumotropica and total bacteria, and changes in vaginal cell type and bacterial counts adhering to vaginal epithelial cells were consecutively investigated. The populations of P. pneumotropica and total bacteria were maximal at oestrus. The increase was correlated with an increase in cornified non-nucleated cells, with large numbers of adherent Gram-negative coccobacilli. The findings indicate that the vagina is a suitable site for colonization by P. pneumotropica in adult female rats, and that proliferation of P. pneumotropica may be due to increased affinity of the organism for cornified non-nucleated cells.     

Ontogenetic changes of circulating erythroid cells and haemoglobin components in Esox lucius

Using light microscopy the morphology, the mitotic index and levels of erythroid cell types were detected from 48 h pike Esox lucius embryos before hatching to adult specimens. At the same developmental stages, the haemoglobins and globin chains expressed were electrophoretically characterized. The erythroid cells of the primitive generation were the most abundant from 48 h before hatching until 15–20 days after hatching, then their number decreased and only rare cells remained in the 3 month‐old juvenile specimens. These cells divided and differentiated in the blood and were substituted by the definitive erythrocyte series. As in other vertebrates, the immature cells of the two generations differed in morphological properties and in the synthetized haemoglobin. The circulating erythroid cells of the definitive population cell lineage were, at all differentiation stages, smaller than those of the primitive generation. The definitive erythrocytes appeared in blood smears of 7 days post‐hatching larvae, they increased rapidly and at 20 days they represented the predominant red blood cell population in the circulation of young pike. Electrophoretic analysis of haemolysates obtained from different developmental stages indicated the presence of distinct embryonic, larval and adult haemoglobins. The embryonic haemoglobins differed from those of the older larva and juvenile specimens and were detectable within the first week of post‐hatching development when only primitive erythrocytes were present in the blood.     

Temporal Characteristics of the Differentiation of Embryonic Erythroid Cells in Fetal Peripheral Blood of the Syrian Hamster

The morphological changes in erythroid cells and their nuclei in the circulation of fetuses of the Syrian hamster were investigated by use of an image-processing system. The analysis included monitoring of nuclear condensation, nuclear periphralization (access of the nucleus to the cell membrane), enucleation, density of cells, and changes in cell size from day 9 of gestation to day 5 after birth. The yolk-sac-derived erythroid cells made rapid progress in nuclear condensation on day 11, while this process proceeded at a much lower rate after day 12 of gestation. The peripheralization of nuclei started on day 10 and reached a maximum on day 11. The frequency of enucleated cells was below 2% on day 11, while it increased to 30% on day 12. Extruded nuclei, most of which were accompanied by a small quantity of cytoplasm, appeared in the circulation on day 12. The most frequently observed diameter of enucleated erythrocytes, which was 10–10.5 μm on day 12, fell gradually to 8–9 μm on day 14. By contrast, the shift from fetal liver erythrocytes to adult erythrocytes occurred in a discontinuous manner. Adult-type erythrocytes were detected after birth with diameters of 5.5–6 μm. Our data allows us to present the schedule of morphological changes during embryonic erythropoiesis and show that the developmental behavior of "primitive" yolk-sac-derived erythroid cells is more closely correlated with that of the "definitive" fetal liver cells than has been considered to be the case to date.     

CYTOMORPHOMETRY OF DEVELOPING RAT LIVER AND ITS APPLICATION TO ENZYMIC DIFFERENTIATION

Quantitative stereological methods have been adapted for the measurement of the volume of liver attributable to parenchymal, hematopoietic, and Kupffer cells and for the measurement of the relative and absolute number (per unit volume) of these cell types and the mean volume of the parenchymal cell. These morphological parameters are the main ones for interpreting the biochemical differentiation of liver. Quantitative changes in these parameters, in rat liver between the 15th day of gestation and adult life, are presented. Despite the large number of hematopoietic cells, the parenchymal cells fill more than half of the liver volume between the 15th and 18th days of gestation and 0.85 of the liver volume at term. The fraction of liver volume occupied by Kupffer cells is never more than 0.02; the number of Kupffer cells per cubic centimeter increases less than twofold between fetal and adult life. The mean volume of individual parenchymal cells undergoes a threefold rise during late fetal life, declines in the neonatal period, and doubles between the 12th and 28th postnatal days. With the morphometric data obtained, it is impossible to convert enzyme concentrations (units per gram, determined in homogenates of whole liver) to enzyme amounts per unit volume of parenchymal or hematopoietic tissue or per individual cell of either type. In late fetal liver, only rises in enzyme concentration less than twofold may be attributed to the enrichment of parenchymal tissue at the expense of hematopoietic elements. The sudden upsurge, by more than twofold, of hepatic enzymes of the late fetal cluster (and also of the neonatal and late suckling cluster) reflects rises per parenchymal mass and per parenchymal cell. Thyroxine and glucagon, the administration of which to fetal rats promotes enzyme differentiation in liver, are without appreciable effect on the cytological parameters studied. Hydrocortisone accelerates the involution of hematopoietic tissue in fetal liver. Enzymes that are diminished by prenatal injection of hydrocortisone may be concentrated in hematopoietic cells.     

The effect of haemorrhage on the cell populations of the thymus and bone marrow in wild starlings (Sturnus vulgaris)

Summary Following the withdrawal of blood from the brachial vein of adult wild starlings (Sturnus vulgaris) changes in the cell populations within the bone marrow and thymus were observed over an eight day period. The packed cell volume, haemoglobin content and reticulocyte count of the peripheral blood was determined before and after haemorrhage.The maximum effect of the haemorrhage was observed in the bone marrow after four days when the population of small lymphocytes, and basophilic erythroid precursors were reduced to less than 1%. At the same time the percentage of another line of erythroid cells increased to 68%. This second erythroid lineage was the major erythroid line in the thymus, and again maximum representation occurred at 4 days post haemorrhage. After this the thymus became predominantly lymphoid and started to increase in size.The two erythroid lines are described and their status with regard to avian thrombocytes is also discussed.The peripheral blood had not attained the pre-haemorrhagic values for reticulocyte counts by eight days although the packed cell volumes and haemoglobin contents were similar.I would like to thank Dr. Peter Ward of the Institute of Terrestrial Ecology for help in obtaining the starlings. Thanks are also due to the staff of the Anatomy Department of St. Thomas's Hospital Medical School, and in particular Mr. Watson. This and other work on the thymus is possible due to the support of the Research (Endowments) Committee of St. Thomas's Hospital     

Developmental changes in erythropoietin receptor expression of fetal mouse liver.

Erythropoietin (EPO) stimulates proliferation and differentiation of late erythroid precursor cells (CFU-E) and thereby determines the rate of erythropoiesis. Liver is the major erythropoietic site in a fetus. We dealt with developmental changes in CFU-E and EPO receptor (EPO-R) of fetal mouse liver. The affinity of the EPO-R to EPO was unchanged during fetal development. The population size of CFU-E, the number of EPO-R per liver cell, and EPO-R mRNA decreased as gestation proceeded, in a pattern indicating that the expression of EPO-R on erythroid precursor cells in fetal mouse liver is governed mostly by the process of mRNA production.     

Red blood cell life span in the ovine fetus

Red cell life span within the fetal circulation has not been reported, although erythrocyte life span has been studied in the adult and newborn. The present study quantified red cell life span in 12 chronically catheterized fetal sheep at 97-136 days gestation (term = 150 days) with the use of autologous red cells labeled with [(14)C]cyanate. Cyanate forms a permanent covalent bond with hemoglobin and acts as a permanent red cell label. In the fetuses, blood (14)C activity decreased in a curvilinear fashion with time and reached 50% of the initial activity at 16.4 +/- 1.6 (SE) days. In contrast, (14)C activity of autologous red cells in two adult ewes decreased linearly with time as expected, reached 50% of the initial (14)C activity in 59 days, and yielded life spans of 117 and 121 days. Computer modeling and parameter optimization taking into account growth and skewed life span distribution were used to analyze the (14)C disappearance curve in each fetus. The mean life span of all red cells in the fetal circulation was 63.6 +/- 5.8 days. Mean red cell life span increased linearly from 35 to 107 days as fetal age increased from 97 to 136 days (r = 0.83, P < 0.001). Life span of cells produced at the time of labeling was significantly greater than the mean life span. Fetal growth rate estimated from parameter optimization was 3.28 +/- 0.72%/day; this compared well with the rate of 3.40 +/- 0.14%/day calculated from fetal weights at autopsy. Mean corpuscular volume decreased as a function of gestational age, but the decrease was small compared with the large increase in red cell life span. We conclude the following: 1) red cell life span in the fetal circulation is short compared with the adult; 2) red cells in younger fetuses have shorter life spans than in near-term fetuses; 3) the curvilinear disappearance of labeled red cells in the fetus appears to be due primarily to an expanding blood volume with fetal growth; and 4) red blood cell life span in a growing organism will be significantly underestimated unless the expansion of blood volume with growth is taken into account.     

Buoyant density, growth rate, and the cell cycle in Streptococcus faecium.

The buoyant density in rapidly growing Streptococcus faecium 9790 cells varies over the cell cycle, in contrast to the density in Escherichia coli. Buoyant density in S. faecium was measured by using Percoll (Pharmacia Fine Chemicals, Piscataway, N.J.) density gradients. We found that the mean and coefficient of variation of the population density increased with growth rate; and within a population, the mean cell volume, which was measured electronically, increased with density. These results were compared with electron microscopic measurements of the size distributions of cell wall growth sites within each fraction of the density gradient. As the density increased within a population, the frequency of large cells increased and the frequency of newly initiated cell wall growth sites increased. These effects were more marked as the growth rate increased. Next, these data were regrouped by cell size by using the size of the central growth site as an index of cell cycle stage. Each frequency value was weighted by the proportion of the population represented by that density fraction. Then, the average buoyant density was calculated for each value of cell size. In all cell populations, the density decreased and then increased as the central site enlarged. Peripheral growth sites were initiated as density reached a maximum. At faster growth rates, density increased more steeply, and new peripheral growth sites opened up at a higher frequency. We suggest that the rate at which density increases during the cell cycle correlates with the initiation of new cell wall growth sites.     

Specificity,avidity, and size of B-lymphocyte populations during ontogeny

The size and specificity of plaque-forming cell precursors (PFC) in murine fetal liver, neonatal, and adult spleen were studied in an adoptive transfer system. In this system, anti-4-hydroxy-3-iodo-5-nitrophenylacetic acid (anti-NIP) and anti-2,4,6-trinitrobenzene sulfonic acid (anti-TNP) direct PFC are generated from bone marrow-derived (B) cell precursors in fetal liver between 17 and 20 days of gestation and in 6- or 14-day neonatal spleen. PFC generated from fetal liver and neonatal and adult spleen cells are specific in that they lyse either NIP-coupled SRBC or TNP-coupled SRBC but not both. The generation of specific anti-NIP and anti-TNP PFC from precursors in fetal liver is primarily independent of antigenic stimulation. In contrast, the anti-NIP and anti-TNP responses generated from neonatal and adult spleen are antigen dependent. Both high-avidity PFC (detected with SRBC indicators coupled at low hapten density) and low-avidity PFC (detected with SRBC coupled at high hapten density) are generated from fetal liver and neonatal spleen cells; however, the proportion of high-avidity PFC precursors in adult spleen is at least threefold greater than in fetal liver or neonatal spleen. Analysis by velocity sedimentation indicates that most high-avidity PFC precursors are small lymphocytes in fetal liver, medium lymphocytes in 6-day neonatal spleen, and small lymphocytes in 14-day-old and adult spleen. Low-avidity PFC precursors are primarily medium-sized lymphocytes in fetal liver and 6-day neonatal spleen. In 14-day-old and adult spleen almost all high- and low-avidity PFC precursors are small lymphocytes. The results are discussed in terms of relative changes in the pool sizes of these lymphocyte populations.     

Intraspecific variation in the population dynamics and growth of the limpet,Cellana tramoserica

Summary Populations of the limpet Cellana tramoserica (Sowerby) from high, mid, and low intertidal regions, and from a subtidal zone, were studied at Cape Banks (N.S.W.), Australia. Individuals from the subtidal population had the largest mean and maximum shell size, the low and high shore populations were intermediate, while the midshore population had both the smallest mean and maximum size. The density of adults showed the reverse trend: the midshore region had the greatest adult population density while the subtidal population had the smallest density. The density of juveniles and recruits was negatively correlated with tidal height in the intertidal areas, but the density of both age-classes was smallest in the subtidal region. The rate of growth of individuals was negatively correlated to the adult density of a site; individuals from the subtidal population grew the fastest, while those from the midshore region grew the slowest. The level of adult mortality of the four populations was similar, with an annual rate of between 50–60%. Juvenile mortality did, however, differ among populations; reduced percentages of juveniles reached adult size in the mid and low shore populations than in the highshore and subtidal populations.The expected lifetime fecundity of individual females differed among the four populations. Subtidal individuals were expected to spawn 40 times the amount of gonad material during their life than were individuals from the midshore population. Individuals from the high and low populations probably spawn 10 times more than those from the midshore region. Differences in the fecundities of individuals were not likely to be the result of genetic differences because experimental transplants and manipulations of density showed that individuals from all the intertidal populations could increase their growth rate to match that of subtidal individuals. The implications of the difference in lifetime fecundity among populations are discussed.