Biochemical and biological characterization of a human Rac2 GTPase mutant associated with phagocytic immunodeficiency.

The Rho GTPase, Rac2, is expressed only in hematopoietic cell lineages, suggesting a specific cellular function in these cells. Genetic targeting studies in mice showed that Rac2 is an essential regulator of neutrophil chemotaxis, L-selectin capture and rolling, and superoxide production. Recently, a dominant negative mutation of Rac2, D57N, has been reported to be associated with a human phagocytic immunodeficiency. To understand further the cellular phenotypes associated with this D57N Rac2 mutant we examined its biochemical characteristics and functional effects when expressed in primary murine bone marrow cells. When compared with wild type (WT) Rac2, D57N Rac2 displayed approximately 10% GTP binding ability resulting from a markedly enhanced rate of GTP dissociation and did not respond to the guanine nucleotide exchange factors. These results suggest that D57N Rac2 may act in a dominant negative fashion in cells by sequestering endogenous guanine nucleotide exchange factors. When expressed in hematopoietic cells, D57N Rac2 reduced endogenous activities of not only Rac2, but also Rac1 and decreased cell expansion in vitro in the presence of growth factors due to increased cell apoptosis. Unexpectedly, D57N expression had no effect on proliferation. In contrast, expansion of cells transduced with WT Rac2 and a dominant active mutant, Q61L, was associated with significantly increased proliferation. Transplantation of transduced bone marrow cells into lethally irradiated recipients showed that the percentage of D57N-containing peripheral blood cells decreased markedly from 40% at 1 month to <5% by 3 months postinjection. Neutrophils derived in vitro from the transduced progenitor cells containing D57N demonstrated markedly impaired migration and O(2)(-) responses to formyl-methionyl-leucyl-phenylalanine, reflecting the same cellular phenotype in these differentiated cells as those described previously in patient cells. These data suggest that the phenotypic abnormalities associated with D57N Rac2 may involve not only neutrophil cellular functions, but also abnormal cell survival in other hematopoietic cells and that overexpression of Rac leads to increased proliferation of normal cells in vitro, whereas deficiency of Rac leads to increased apoptosis.

Dominant negative mutation of the hematopoietic-specific Rho GTPase, Rac2, is associated with a human phagocyte immunodeficiency.

Rho GTPases control a variety of cellular processes, including actin polymerization, integrin complex formation, cell adhesion, gene transcription, cell cycle progression, and cell proliferation. A patient is described who has recurrent infections and defective neutrophil cellular functions similar to those found in Rac2-deficient mice. Molecular methods were used to clone the expressed Rac2 cDNA from this patient, and a single base pair change (G-->A at nucleotide 169) in the coding sequence was identified. This results in an asparagine for aspartic acid mutation at amino acid 57 (D57N), a residue that is involved in nucleotide binding and is conserved in all mammalian Rho GTPases. The cloned cDNA was then introduced into normal bone marrow cells through retrovirus vectors, and neutrophils expressing this mutant exhibited decreased cell movement and production of superoxide in response to fMLP. The expressed recombinant protein was also analyzed biochemically and exhibited defective binding to GTP. Functional studies demonstrated that the D57N mutant behaves in a dominant-negative fashion at the cellular level. The syndrome of Rac2 dysfunction represents a human condition associated with mutation of a Rho GTPase and is another example of human disease associated with abnormalities of small G protein signaling pathways. (Blood. 2000;96:1646-1654)

Osmometric and permeability characteristics of human placental/umbilical cord blood CD34+ cells and their application to cryopreservation.

The transplantation of placental/cord blood-derived HPC (e.g., CD34+ cells) has become a useful treatment for a broad spectrum of malignant and nonmalignant diseases. The ability to cryopreserve this cell type with high efficiency adds considerable flexibility to cord blood transplantation. The purpose of this study was to develop an understanding of the fundamental cryobiologic factors of these cells, including the osmotic/permeability characteristics, and to use a theoretical approach to optimize freezing procedures. To that end, biophysical parameters, including the osmotically inactive cell volume (Vb), hydraulic conductivity (Lp), and cryoprotectant permeability coefficient (P(CPA)) for DMSO and propylene glycol were measured using a modified Coulter Counter (Coulter Electronics, Inc., Hialeah, FL) at 22 degrees C. In addition, the osmotic tolerance of PCB CD34+ cells was assessed using a colony-forming assay. These experimentally determined parameters were used in a mathematical model to predict optimal cryoprotectant addition and removal procedures. The results demonstrate a Vb of 0.32 x V(iso), an average Lp of 0.17 +/- 0.03 (microm/min/atm +/- SD), and a PCPA of 0.94 +/- 0.004 or 1.0 +/- 0.004 cm/min (x10(-3)) for DMSO or propylene glycol, respectively. No significant difference was determined between the two cryoprotectants used. The osmotic tolerance limits were determined to be 200 and 600 mOsm/kg (1.29 and 0.62 x V(iso), respectively). These results indicate potential benefits of modifications to the widely used method of Rubinstein et al. Proc Natl Acad Sci USA 92:10119-10122, 1995) for cord blood CD34+ cell cryopreservation. As opposed to Rubinstein's method in which DMSO is added to cooled cell suspensions over a 15-min interval, our data indicate that better results may be obtained by introducing and removing the cryoprotectant at ambient temperature over 5 min both to increase viability by avoiding unnecessary risks from osmotic shock and to simplify the protocol. In addition, substitution of propylene glycol for DMSO may be of benefit during the actual freezing and thawing process.

Previous loss of chromosome 11 containing a suppressor locus increases radiosensitivity, neoplastic transformation frequency and delayed death in HeLa x fibroblast human hybrid cells.

CGL1 (HeLa x fibroblast) hybrid cells have been utilized to study mechanisms of radiation-induced neoplastic transformation of human cells in vitro. Previous analysis has shown that loss of active tumor suppressor alleles on fibroblast chromosomes 11 and 14 may be required for radiation-induced neoplastic transformation of CGL1 cells. Loss of chromosome 11 alone was, therefore, found to be necessary but not sufficient for neoplastic transformation. We postulated that the loss of chromosome 11 may make the hybrid cells more susceptible to radiation-induced neoplastic transformation, since these cells have already undergone one of the required tumor suppressor loss events. Hybrid cells which have lost one copy of chromosome 11 were designated CON104(-11). CON104(-11) hybrid cells were found to have increased X-ray sensitivity and susceptibility to radiation-induced neoplastic transformation when compared with the parental CGL1 cells. In addition, the neoplastically transformed foci appear to arise earlier after radiation exposure in CON104(-11) versus CGL1 cells. Furthermore, the plating efficiency (PE) of the progeny of the irradiated CON104(-11) cells, growing in transformation flasks, is persistently lower than parental CGL1 cells during the 21 day assay period. The lower PE of the progeny of irradiated cells was attributed to the expression of delayed death/lethal mutations post-irradiation, a reflection of genomic instability. Taken together, the data indicate that previous loss of chromosome 11 may increase the radiation-induced genomic instability of the hybrid cells, leading to increased radiation sensitivity and neoplastic transformation potential. The data suggest that one possible function of the chromosome 11 tumor suppressor gene may be to help maintain genome stability after radiation damage.