Comparative studies of different stromal cell microenvironments in support of human B-cell development.

This study compared human murine stromal cells for their capacity to support human hematopoietic stem cell (HSC) development into the B lineage. FACS sorted human fetal bone marrow (BM) HSC (CD34+CD19- or CD34+/CD10-/CD19-/CD45RA) were cultured on human fetal BM stromal cells, human skin fibroblasts, or murine S17 stromal cells and analyzed by flow cytometry or reverse transcriptase polymerase chain reaction. CD34+CD19- HSC on human BM stromal cells or fibroblasts differentiated into B-lineage cells with a continuum in density of surface CD19 expression, and some cells expressing micro/kappa or micro/lambda B-cell receptors. In contrast, CD19+ cells from S17 cultures had two- to fourfold higher levels of CD19, but no cells expressing B-cell receptors. The number and percentage of CD19+ cells was high, intermediate, or low in the human BM, human fibroblast, or murine S17 stromal cell cultures, respectively. Reverse transcriptase polymerase chain reaction analysis showed that TdT, CD19, and DHQ52-J(H) rearrangements were expressed at comparable levels when CD34+/CD19- HSC were plated on human or murine stromal cells. In contrast, CD34+/CD10-/CD19-/CD45RA HSC plated on human or murine stromal cells expressed CD19 in both cultures, but TdT was only expressed in human stromal cell cultures. We conclude that human BM stromal cell, human skin fibroblasts, and murine S17 stromal cell cultures can provide complementary and comparative tools for identification of stromal cell ligands with potentially unique functions in regulating human B-cell development.

Microenvironmental influences on human B-cell development.

Mammalian B-cell development can be viewed as a developmental performance with several acts. The acts are represented by checkpoints centered around commitment to the B-lineage and functional Ig gene rearrangement--culminating in expression of the pre-B-cell receptor (pre-BCR) and the BCR. Progression of cells through these checkpoints is profoundly influenced by the fetal liver and adult bone marrow (BM) stromal cell microenvironments. Our laboratory has developed a model of human B-cell development that utilizes freshly isolated/non-transformed human BM stromal cells as an in vitro microenvironment. Human CD34+ hematopoietic stem cells plated in this human BM stromal cell microenvironment commit to the B lineage and progress through the pre-BCR and BCR checkpoints. This human BM stromal cell microenvironment also provides survival signals that prevent apoptosis in human B-lineage cells. Human B-lineage cells exhibit differential expression of Notch receptors and human BM stromal cells express the Notch ligand Jagged-1. These results suggest a potential role for Notch in regulating B-lineage commitment and/or progression through the pre-BCR and BCR checkpoints.