Segregation of mouse hemopoietic progenitor cells using the monoclonal antibody,YBM/42

A rat monoclonal antibody, YBM/42, directed against mouse leukocyte common antigen, was used for the analysis and separation of hemopoietic progenitor cells from mouse bone marrow and fetal liver. Cells were fractionated on a FACS-II cell sorter and the resulting subpopulations examined for their morphology and ability to form colonies in agar (for day 7 colonies) and methylcellulose (for day 2 erythroid clones). The antibody bound to all leukocytes, including blast cells and day 7 hemopoietic progenitor cells (day 7 colony forming cells, CFC), but not to erythrocytes or nucleated erythroid cells. This antibody can be used to advantage to enrich for early progenitor cells from mouse fetal liver, in which the majority of cells (70%) are nucleated erythroid cells. In day 12 fetal liver, approximately 10% of all cells bind this antibody strongly and, of these approximately 70% are blast cells. Contained within this positive population are 95% of all day 7 CFC. In the most enriched fraction about 20% of the cells formed day 7 colonies. This represents a 25-fold enrichment over unsorted fetal liver. The negative fractions contain 94% of all cells forming erythroid clones (≥8 cells) on day 2 of culture (day 2 CFU-E). In the most enriched fraction, 20% of the cells are day 2 CFU-E. Day 7 CFC can therefore be well separated from day 2 CFU-E, with good recovery of both cell types, by use of a single label. Day 7 colony forming cells were classified as granulocyte (G-CFC), macrophage (M-CFC), mixed granulocyte/macrophage (GM-CFC), pure erythroid (E), or mixed erythroid (E_mix). A high enrichment for multipotential cells is achieved and constitues 3–5% of cells in the most enriched fraction. Most types of day 7 CFC could not be separated with YMB/42, but GM-CFC and M-CFC exhibit a broader distribution than the other CFC with regard to fluorescence intensity. This implicit heterogeneity in GM-CFC and M-CFC is further substantiated by the finding that myeloid progenitors in the different FACS fractions also share a differential reactivity to different sources of growth factors.     

The embryonic thymus produces chemotactic peptides involved in the homing of hemopoietic precursors

During ontogeny, T cell precursors must colonize the thymus to acquire immunocompetency. Using migration assays, a chemotactic activity was detected in conditioned media from avian embryonic thymic epithelial cells. The responding cells were shown to acquire T lymphocyte markers after homing into the thymus. Absorption experiments demonstrated surface receptors for the chemotactic substance on these hemopoietic precursors, which were not found on thymus-derived lymphocytes. Two peaks of chemotactic activity in the 1 kd-4 kd molecular weight range were detected after fractionation of thymic epithelial cell-conditioned medium. One of these activities was retained after heating to 95 degrees C but was destroyed after proteolytic treatment. Thus chemotactic peptides may be responsible for the thymic recruitment of the first hemopoietic precursors and may also be involved in the renewal of these precursors throughout adult life.     

Extrinsic and intrinsic cholinergic systems of the vascular wall.

Immunohistochemical, biochemical and functional studies have revealed two separate cholinergic systems in the arterial vascular wall. Endothelial cells represent the ubiquitous intrinsic, intimal system; they contain the acetylcholine-synthesizing enzyme, choline acetyltransferase, release a choline ester, and contain functional muscarinic receptors. Perivascular autonomic nerve fibres represent the extrinsic, adventitial system. These axons are not ubiquitous but show a highly selective distribution among and even within organs, and utilize co-mediators (NO, neuropeptides) in an organ-specific pattern. We put forward the hypothesis that the intrinsic, intimal system serves as a general regulator of basal vascular tone and wall structure responding to local, luminal stimuli, whereas the perivascular nerve fibres act on top of this basal tone by providing fine tuning in response to reflex activation due to systemic demands.     

Dysregulation pathology of hemopoietic and immune systems under infectious process

Blood system and immune system play the crucial role in maintenance of anti-infectious defence of macroorganism. Meanwhile, infectious agents, differencing by their nature, have marked mutafacient effect on immunocompetent cells of blood. Dysregulation of DNK-reparation systems, apoptosis and immunity, maintaining genetic homeostasis of organism, is considered to be the basic reason of cytogenetic instability under infectious process. It has been established, that disturbances in blood and immunity systems, following infectious process, are caused by not only direct or indirect action of infectious agents on mature immunocytes, but else by their stimulating or suppressed influence on functional properties of early cells-precursors of hemo- and immunopoesis and hemopoietic microenvironment.     

Segregation distortions of the ABO and Rh systems in malformed newborns

This study compares the segregation of the ABO and Rh systems between malformed newborns and a control group with two purposes: (1) to evaluate the participation of genetic factors associated with these blood groups in the production of congenital malformations, and (2) to prove, indirectly, the existence of reproductive losses associated with congenital malformations. The newborns and their mothers were typed for ABO and Rh groups. Gene frequencies were similar in malformed and control newborns. In the female malformed newborns, an excess of O-B pairs and a deficit of B-B pairs in the ABO system, and an excess of Rh(-)-Rh- pairs in the Rh system were found.     

Mechanotransduction in embryonic vascular development

A plethora of biochemical signals provides spatial and temporal cues that carefully orchestrate the complex process of vertebrate embryonic development. The embryonic vasculature develops not only in the context of these biochemical cues, but also in the context of the biomechanical forces imparted by blood flow. In the mature vasculature, different blood flow regimes induce distinct genetic programs, and significant progress has been made toward understanding how these forces are perceived by endothelial cells and transduced into biochemical signals. However, it cannot be assumed that paradigms that govern the mature vasculature are pertinent to the developing embryonic vasculature. The embryonic vasculature can respond to the mechanical forces of blood flow, and these responses are critical in vascular remodeling, certain aspects of sprouting angiogenesis, and maintenance of arterial–venous identity. Here, we review data regarding mechanistic aspects of endothelial cell mechanotransduction, with a focus on the response to shear stress, and elaborate upon the multifarious effects of shear stress on the embryonic vasculature. In addition, we discuss emerging predictive vascular growth models and highlight the prospect of combining signaling pathway information with computational modeling. We assert that correlation of precise measurements of hemodynamic parameters with effects on endothelial cell gene expression and cell behavior is required for fully understanding how blood flow-induced loading governs normal vascular development and shapes congenital cardiovascular abnormalities.     

The expression of fetuin in the development and maturation of the hemopoietic and immune systems

 The distribution and expression of fetuin, a fetal plasma protein that has been shown to have a widespread intracellular presence in many developing tissues including the central nervous system, has been studied in the developing immune and hemopoietic organs of fetal and adult sheep. The presence of fetuin was demonstrated using immuno-cytochemistry and expression of fetuin was studied using northern blot analysis and in situ hybridization. In the developing sheep fetus, fetuin was shown to be expressed first in the hemopoietic cells of the fetal liver and subsequently in the forming spleen. The very first stromal, bone marrow-forming cells, also expressed fetuin mRNA. These cells became more numerous during gestation and by embryonic day (E)115 (term is 150 days), fetuin-expressing cells were identified morphologically to be monocytes/macrophages. Fetuin protein, on the other hand, was present in all hemopoietic and immune organs from the earliest age studied (E30) but was confined initially to matrix, mesenchymal tissue. Fetuin-positive cells could be identified in the spleen at E60 as early hemopoietic cells, in the lymph nodes at E60 as stromal cells and macrophages, and at E115 in the thymus as macrophages and squamous cells. In the adult, fetuin mRNA was only detectable by northern blot in the liver and the bone marrow. Using in situ hybridization in adult tissue, fetuin mRNA-positive cells were identified in the bone marrow to be monocytes/macrophages. Additionally, in the spleen germinal centres, fetuin mRNA was identified in cells with the morphology of dendritic cells. Using three separate cellular markers: lysozyme, S-100, and α₁-antitrypsin, the cellular identification of fetuin-positive cells was confirmed to be in the monocyte/macrophage lineage. Accepted: 3 May 1996     

Segregation and linkage analysis.

Computer programs are available in the software package SAGE to perform a variety of segregation and linkage analyses used by human geneticists. These methods are designed specifically to uncover major gene segregation in pedigree data coming from non-inbred populations. With the aid of a closely linked polymorphic marker, they can detect a locus that contributes as little as 10% to the variation of a quantitative trait in a pedigree sample of several hundred individuals.     

Changes in the vascular extracellular matrix during embryonic vasculogenesis and angiogenesis

We have previously characterized monoclonal antibodies against chick brain cells. One of them (14-2B2) brightly stained all capillaries in frozen sections of chick brain. Here we show that this antibody is directed against chick fibronectin. Using this antibody and polyclonal antibodies against laminin, we have studied the development of the vascular extracellular matrix. Vasculogenesis, the development of capillaries from in situ differentiating endothelial cells, was studied in yolk sac blood islands and intraembryonic dorsal aorta. Blood islands produced high levels of fibronectin but not laminin. Early intraembryonic capillaries all expressed fibronectin but little if any laminin. The dorsal aorta of a 6-day-old chick embryo has several layers of fibronectin-producing cells, but is devoid of laminin. Laminin expression commenced at Day 8 and by Day 10 an adult-like distribution was found in the aortic vascular wall. Angiogenesis, the formation of capillaries from preexisting vessels, was studied during brain development. Capillary sprouts invading the neuroectoderm at Embryonic Day 4 migrated in a fibronectin-rich matrix devoid of laminin. Ultrastructural immunolocalization demonstrated the presence of fibronectin exclusively on the abluminal site of the endothelial cells. Beginning on Day 6, laminin codistributed with fibronectin in brain capillaries. We conclude that immature capillaries migrate and proliferate in a fibronectin-rich extracellular matrix, which is subsequently remodeled acquiring basement membrane-like characteristics. We suggest that laminin expression is an early indication of vascular maturation.     

Dialectics, systems biology and embryonic induction

A hallmark of embryonic development is the temporal-spatial continuum of cell-cell interactions, which gives rise to the trajectory of progressive cell differentiations. Despite the great reductionists' success in dissecting the mechanistic basis of developmental processes, the call for more holistic system theories never ceased during the last century. Various system theories were proposed to provide a more adequate understanding of biological systems, including development. Although widely ignored by modern biology, the first systematic system theory was Hegel's dialectics. Here I examine the process of embryonic induction as elaborated by Hans Spemann in the light of dialectics. I conclude that embryonic induction and its underlying molecular mechanisms can be re-interpreted in terms of Hegel's dialectics. The example highlights that despite its shortcomings, dialectics can be of heuristic value as a theory of systems biology.     

Optimal systems: I. The vascular system

An approach to quantitative work on optimal systems is considered. Desired optimal principles are utilized in constructing a hypothetical system similar to the organ system considered. A comparison of this constructed system with the anatomical system then gives an indication of the importance of the optimal principles in the form or function of the organ system considered. These ideas are applied to the mammalian vascular system, and limiting values are obtained for some of its important component parts. The constructed system gives good agreement with anatomical data for vessel radii, lengths, and hydrodynamic resistance to flow.     

Optimal systems: II. The vascular system

A refinement of a model of the vascular system (Cohn, 1954) is discussed. We now consider that the major vessels arise from the aorta as secondary branching vessels rather than by successive dichotomies of the aorta as previously considered. It is shown that this change does not affect calculated values of flow, the number of branchings, or the relative radii of vessels at a branching. A comparison is made of theoretical predictions with experimental data and good greement is found. The method of analysis of this paper is used to extend the treatments of the previous paper to a more general case. It is shown that the results previously obtained are valid.     

In vitro production of hemopoietic stem cells: washings from organ cultures of embryonic liver]

Hemopoietic cells including CFUs could be washed off from the organ culture of fetal liver periodically for 4 weeks. Under the cultivation conditions employed this treatment did not reduce the CFUs content of the culture essentially; thus, the washings off could be used to elevate the CFUs yield per culture.