Isolation and characterization of Leishmania mutants defective in glycosomal protein import.

Kinetoplastid parasites contain a unique microbody organelle called the glycosome. Several important metabolic pathways found in the cytoplasm of higher eukaryotes are compartmentalized within the glycosome in these pathogens. This fundamental difference between the host and parasite has led to consideration of the glycosome as a potential chemotherapeutic target. The genetic basis of glycosome biogenesis is therefore of great interest. This report describes the isolation of multiple Leishmania mutant cell lines defective in glycosomal protein import, and the detailed characterization of three such lines. The mutants examined partially mislocalize a subset of glycosomal proteins to the cytosol yet retain wild-type numbers of glycosomes. One of the mutants has a mutation in the previously identified LdPEX2 (GIM1) gene. The other two mutants are demonstrated to contain cell-specific lesions in one or more genes distinct from PEX2. The identification of multiple genetically distinct mutants with defects in glycosome import provides an important genetic tool to facilitate the identification of genes involved in glycosome biogenesis.

Efficient retroviral mediated transfer of the glucocerebrosidase gene in CD34+ enriched umbilical cord blood human hematopoietic progenitors.

Obtaining efficient transfer of a normal gene and its sustained expression in self-renewing hematopoietic stem cell populations is a central concern for gene therapy initiatives. Potentially, 10(8) to 10(9) CD34+ enriched cells per patient will be required for transduction and subsequent reimplantation. These studies present an efficient method for the transduction of human CD34+ cells that can be used in a clinical study of gene transfer. The method uses a centrifugation-enhanced technique for the retroviral-mediated transfer of the normal human glucocerebrosidase (GC) gene to human CD34+ enriched umbilical cord blood cells (CB). Previous studies had described high expression of GC in CD34+ enriched cells but had not reported transduction efficiency in the progenitor population specifically. The data demonstrate an average transduction efficiency in the progenitor cell population of 50% as measured by polymerase chain reaction (PCR) for the integrated GC-cDNA in clonogenic cells. Measurements of enzyme activity comparing transduced and nontransduced fractions at 6 days posttransduction indicate an average enzyme increase of six-fold over normal background levels. PCR of colony forming units-granulocyte/macrophage (CFU-GM) plated at 6 weeks from long-term culture-initiating cell (LTC-IC) cultures also indicates transfer of the transgene to early progenitor cells. Finally, experiments were carried out with the human erythroleukemia cell line, TF-1, to estimate the durable expression of the transgene. Enzymatic activities in transduced TF-1 cultures remained at 30-fold above the activity of nontransduced controls. The expression persisted for 6 weeks in culture. These studies demonstrate efficient transduction of early progenitor cells and sustained expression of the transgene in cell cultures.

Cytokine mobilization of peripheral blood stem cells in patients with Gaucher disease with a view to gene therapy.

As clinical trials for gene therapy in Gaucher disease (GD) begin, questions regarding the biology of the hematopoietic stem cell in this disease remain unanswered. This study demonstrates the ability to mobilize and collect CD34+ cells in three patients with the disorder. Our RAC/FDA-approved clinical trial utilizes mobilized peripheral blood stem cells (PBSC) as the target cells for gene transfer. In this approach, a white blood cell fraction is collected by apheresis, enriched for CD34+ cells, and transduced with a retroviral vector carrying the glucocerebrosidase (GC) gene. Transduced cells from the patient with activity corrected to at least normal levels will be returned to the patient without myelosuppressive therapy. We report here the effect of cytokines in mobilizing PBSC in three patients with GD. Two (patients 1 and 2) were given granulocyte colony-stimulating factor (G-CSF) at a dose of 5 micrograms/kg/d and one (patient 3) was given 10 micrograms/kg/d for 10 days. Leukaphereses were done daily for 5 days and the products enriched for CD34+ cells using the clinical Ceprate (CellPro) column. The CD34+ cells in all fractions were monitored daily during mobilization and leukaphereses. Subset analysis for the expression of Thy-1, CD38, HLA-DR, and CD33 on the CD34+ cells was performed. An increase in CD34+ cells in the peripheral blood was noted from day 5 onward (up to a six-fold increase). Up to a 625-fold enrichment in CD34+ cells in the apheresis product was noted using the clinical Ceprate column. Totals of 1.2, 3.5, and 2.1 x 10(6) CD34+ cells/kg were collected in the three patients. A diminution in the percent of CD34+/Thy-1+ cells was noted with enrichment. In vitro retroviral transduction of the CD34-enriched cells using centrifugation promoted transduction protocol previously described (Bahnson AB et al., Centrifugal enhancement of retroviral-mediated gene transfer. Journal of Virology Methods 54:131, 1995) and modified for clinical use, demonstrated a mean transduction efficiency of 37% (range 8.3-87.1%) in clonogenic cells and up to 50% in long-term culture-initiating cells (LTC-IC) at week 6. Significantly, we have been able to achieve up to a 50-fold increase in the level of GC above deficient levels in the patients' CD34+ enriched cells when maintained in vitro in culture. The study demonstrates that up to a six-fold increase in CD34+ cells in the PB can be achieved with cytokines in patients with GD. CD34+ cells can be collected in numbers sufficient for conventional transplantation and transduced efficiently in vitro. In gene therapy trials for genetic disorders to date, myelosuppressive therapy is not advocated. The clinical trial will demonstrate whether this number of transduced CD34+ cells will be adequate for competitive engraftment of genetically corrected PBSC.

Long-term expression of the glucocerebrosidase gene in mouse and human hematopoietic progenitors.

Gaucher disease (GD), one of the most common inherited metabolic disorders, is an excellent candidate for gene therapy using hematopoietic stem cells as targets. Animal models have demonstrated the feasibility of introducing the human glucocerebrosidase (GC) gene into hematopoietic progenitors with long term expression using a variety of retroviral vectors. We have previously demonstrated the expression and integration of the human GC gene in mouse hematopoietic progenitors and their progeny 4-8 months post transplant in primary recipients using the retroviral vector MFG-GC. We now demonstrate enzyme expression in peripheral blood lymphocytes of secondary recipients more than 12 months post transplantation. We also show a transduction efficiency of up to 95% in colony forming unit-granulocyte macrophage (CFU-GM) colonies generated from transduced CD34+ cells from a variety of sources, using a centrifugation promoted infection protocol. Transduction has also been documented in long term culture initiating cells (LTCIC) from the same transduced CD34+ cells. These data indicate efficient transduction of mouse hematopoietic progenitors as well as human CD34+ cells using the retroviral vector MFG-GC.

The protein tyrosine kinase substrate cortactin is differentially expressed in murine B lymphoid tumors.

Src family protein tyrosine kinases (PTKs) actively participate in signal transduction during lymphocyte activation. However, little is known about the roles of PTKs and their substrates in lymphocyte differentiation. To identify PTK substrates that may be differentially expressed during B lymphopoiesis, we screened a panel of murine B lymphoid tumor cell lines representing various developmental stages using monoclonal antibodies (MAbs) specific for pp60src substrates. A MAb specific for cortactin, a filamentous-actin binding pp60src substrate, immunoprecipitated proteins from murine plasma-cytoma cell lines but not from pre-B cell lymphoma or B cell lymphoma cell lines. We have cloned a murine cortactin cDNA which encodes a member of a family of proteins distinguished by amino-terminal repeat domains and carboxy-terminal Src Homology 3 domains. Two members of this family (cortactin and HS1) were differentially expressed in murine B lymphoid tumor cell lines; both were detected in plasmacytoma cell lines, however HS1 was additionally detected in pre-B lymphoma and B lymphoma cell lines. Cortactin RNA was detected in most murine tissues, but was not detected in B lymphocytes or plasma cells. We hypothesize that cortactin expression is associated with transformed plasma cells and not with the terminal differentiation of normal B lymphocytes to plasma cells.