Precursor Information and Courses from MediaLab, Inc.

20 to 60% of red cell precursors seen in bone marrow slides normally contain siderotic iron granules visible with Prussian Blue stain. The presence of sideroblasts and siderocytes indicates that the red cell precursors have an ample supply of iron. When a red cell precursor contains too much iron, the siderotic granules form a ring around the nucleus and the resulting cells are referred to as ring sideroblasts. The ring sideroblast is an abnormal (pathological) form of sideroblast.

Activated factor X (Xa), in the presence of factor V (necessary cofactor), ionized calcium, and platelet factor act to convert prothrombin (precursor) to its active form, thrombin, by cleaving the prothrombin molecule.

Within the hematopoietic cords each cell line has a specific location for development. Erythroid precursors are located near a venous sinusoid and cluster around a macrophage. This is referred to as an erythroblastic island. Developing red cells obtain iron needed for hemoglobin production from macrophages. Megakaryocytes are also located close to a venous sinus. They extend their cytoplasm in fingerlike projections through the sinus wall in order to release their platelets directly into the blood in the sinus. Immature granulocytes lie within the hematopoietic cords. The metamyelocyte stage is the first stage of the granulocyte series that is motile and able to move toward the sinus area. Mature neutrophils, eosinophils and basophils enter the sinusoidal blood through the basement membrane. As maturing erythrocytes also move toward the sinus wall any remaining nuclei are lost as the red cells move through small openings in the cells lining the sinus wall.

The site of iron storage in the bone marrow is the macrophage. This is a bone marrow smear showing a macrophage containing near the top of the smear showing clumps of blue-staining material, which is iron. Notice the number of young red cells (erythroid precursors) clustered around the iron in the lower portion of the slide.

This smear is shown under low power (10x objective) magnification. The reddish cells in the background are mature red blood cells. The dark dots are nucleated erythroid and myeloid precursors. The large dark dot in the middle is a megakaryocyte. Normally, about 5 to 10 megakaryocytes are seen per microscopic field at low power magnification. Clusters of megakaryocytes usually indicate megakaryocytic hyperplasia. Less than 2 megakaryocytes per low power field may mean megakaryocytic hypoplasia.

Another example of a normal M:E ratio in a thicker, more representative area of the smear. The cells shown by the arrows are erythroid precursors.

The actual cell count is performed using the oil (100x) objective. This oil immersion field shows a representative counting field. Four granulocytes, a prorubricyte, and two rubricytes are completely visible here. 100 to 500 nucleated cells are generally counted,depending on the cellularity of the smear, and only cells completely visible in the field should be included in the count. The morphology of erythroid and myeloid precursor cells is described in detail in "Introduction to Hematopoiesis" and will not be repeated here.

This low power view of a hematoxyln and eosin stained bone marrow biopsy shows fat cells as clear circles, and the darker intervening areas as blood cell precursors. This biopsy is about 25% cellular, or mildly hypocellular. A normal marrow in a middle aged adult is about 50% cellular.

Specific sugars, attached to the red cell membrane in unvarying linkage conformations, determine ABO antigenic activity. Galactose resides at the end of this specific sugar chain. This configuration constitutes the ABO antigen precursor substance.

As mentioned previously, the A and B genes cannot act directly on the precursor substance. Thus, since individuals with the Bombay phenotype have only the precursor substance and no H antigen, they cannot have A or B antigens, even if they have the A and/or B gene.