Lentiviral vectors targeting WASp expression to hematopoietic cells, efficiently transduce and correct cells from WAS patients.

Gene therapy has been proposed as a potential treatment for Wiskott-Aldrich syndrome (WAS), a severe primary immune deficiency characterized by multiple hematopoietic-specific cellular defects. In order to develop an optimal lentiviral gene transfer cassette for this application, we compared the performance of several internal promoters in a variety of cell lineages from human WAS patients. Vectors using endogenous promoters derived from short (0.5 kb) or long (1.6 kb) 5' flanking sequences of the WAS gene, expressed the transgene in T, B, dendritic cells as well as CD34(+) progenitor cells, but functioned poorly in non-hematopoietic cells. Defects of T-cell proliferation and interleukin-2 production, and the cytoskeletal anomalies in WAS dendritic cells were also corrected. The levels of reconstitution were comparable to those obtained following transduction with similar lentiviral vectors incorporating constitutive PGK-1, EF1-alpha promoters or the spleen focus forming virus gammaretroviral LTR. Thus, native regulatory sequences target the expression of the therapeutic WAS transgene to the hematopoietic system, as is naturally the case for WAS, and are effective for correction of multiple cellular defects. These vectors may have significant advantages for clinical application in terms of natural gene regulation, and reduction in the potential for adverse mutagenic events.

Characterization of an IL-2 mimetic with therapeutic potential.

Human interleukin-2 (IL-2) interacts with two types of functional receptors (IL-2R alpha betagamma and IL-2R betagamma) and acts on a broad range of target cells involved in inflammatory reactions and immune responses. IL-2 is also used in different clinical trials aimed at improving the treatment of some cancers and the recovery of CD4 lymphocytes by HIV patients. The therapeutic index of IL-2 is limited by various side effects dominated by the vascular leak syndrome. We have shown that a chemically synthesised fragment of the IL-2 sequence can fold into a helical tetramer likely mimicking the quatemary structure of an hemopoietin. Indeed, peptide p1-30 (containing amino acids 1 to 30, including the sequence corresponding to the entire alpha helix A of IL-2) spontaneously folds into an alpha-helical homotetramer and stimulates the growth of T-cell lines expressing human IL-2R beta, whereas shorter versions of the peptide lack helical structure and are inactive. At the cellular level, p1-30 induces lymphokine-activated killer (LAK) cells and preferentially activates CD8 low lymphocytes and natural killer cells, which constitutively express IL-2R beta. A significant IFN-gamma production is also detected following p1-30 stimulation. A mutant form of p1-30 (Asp20-->Lys) which is likely unable to induce vascular leak syndrome remains capable to generate LAK cells like the original p1-30 peptide. Altogether our data suggest that p1-30 has therapeutic potential.

IL-2R beta agonist P1-30 acts in synergy with IL-2, IL-4, IL-9, and IL-15: biological and molecular effects.

From the sequence of human IL-2 we have recently characterized a peptide (p1-30), which is the first IL-2 mimetic described. P1-30 covers the entire alpha helix A of IL-2 and spontaneously folds into a alpha helical homotetramer mimicking the quaternary structure of a hemopoietin. This neocytokine interacts with a previously undescribed dimeric form of the human IL-2 receptor beta-chain likely to form the p1-30 receptor (p1-30R). P1-30 acts as a specific IL-2Rbeta agonist, selectively inducing activation of CD8 and NK lymphocytes. From human PBMC we have also shown that p1-30 induces the activation of lymphokine-activated killer cells and the production of IFN-gamma. Here we demonstrate the ability of p1-30 to act in synergy with IL-2, -4, -9, and -15. These synergistic effects were analyzed at the functional level by using TS1beta, a murine T cell line endogenously expressing the common cytokine gamma gene and transfected with the human IL-2Rbeta gene. At the receptor level, we show that expression of human IL-2Rbeta is absolutely required to obtain synergistic effects, whereas IL-2Ralpha specifically impedes the synergistic effects obtained with IL-2. The results suggest that overexpression of IL-2Ralpha inhibits p1-30R formation in the presence of IL-2. Finally, concerning the molecular effects, although p1-30 alone induces the antiapoptotic molecule bcl-2, we show that it does not influence mRNA expression of c-myc, c-jun, and c-fos oncogenes. In contrast, p1-30 enhances IL-2-driven expression of these oncogenes. Our data suggest that p1-30R (IL-2Rbeta)(2) and intermediate affinity IL-2R (IL-2Rbetagamma), when simultaneously expressed at the cell surface, may induce complementary signal transduction pathways and act in synergy.

The first alpha helix of interleukin (IL)-2 folds as a homotetramer, acts as an agonist of the IL-2 receptor beta chain, and induces lymphokine-activated killer cells.

Interleukin (IL)-2 interacts with two types of functional receptors (IL-2Ralphabetagamma and IL-2Rbetagamma) and acts on a broad range of target cells involved in inflammatory reactions and immune responses. For the first time, we show that a chemically synthesized fragment of the IL-2 sequence can fold into a molecule mimicking the quaternary structure of a hemopoietin. Indeed, peptide p1-30 (containing amino acids 1-30, covering the entire alpha helix A of IL-2) spontaneously folds into an alpha-helical homotetramer and stimulates the growth of T cell lines expressing human IL-2Rbeta, whereas shorter versions of the peptide lack helical structure and are inactive. We also demonstrate that this neocytokine interacts with a previously undescribed dimeric form of IL-2Rbeta. In agreement with its binding to IL-2Rbeta, p1-30 activates Shc and p56(lck) but unlike IL-2, fails to activate Janus kinase (Jak)1, Jak3, and signal transducer and activator of transcription 5 (STAT5). Unexpectedly, we also show that p1-30 activates Tyk2, thus suggesting that IL-2Rbeta may bind to different Jaks depending on its oligomerization. At the cellular level, p1-30 induces lymphokine-activated killer (LAK) cells and preferentially activates CD8(low) lymphocytes and natural killer cells, which constitutively express IL-2Rbeta. A significant interferon gamma production is also detected after p1-30 stimulation. A mutant form of p1-30 (Asp20-->Lys), which is likely unable to induce vascular leak syndrome, remains capable of generating LAK cells, like the original p1-30 peptide. Altogether, our data suggest that p1-30 has therapeutic potential.

Analysis of human IL-2/IL-2 receptor beta chain interactions: monoclonal antibody H2-8 and new IL-2 mutants define the critical role of alpha helix-A of IL-2.

Interleukin 2 (IL-2) interacts with a receptor (IL-2R) composed of three subunits (IL-2R alpha, IL-2R beta and IL-2R gamma). IL-2R beta plays a critical role in signal transduction. An anti-human IL-2 mAb (H2-8) produced after immunization with peptide 1-30 of IL-2 was found to recognize the region occupied by Asp20, at the exposed interface between alpha-helices A and C. Muteins at position 17 and 20 are not recognized by mAb H2-8. mAb H2-8 specifically inhibits the IL-2 proliferation of TS1beta cells which are dependent on the expression of human IL-2R beta chain for IL-2 proliferation. Substitution at internal position Leu17 demonstrates that this position is essential for IL-2 binding and IL-2 bioactivity. New IL-2 mutants at position Asp20 have been analysed. Substitutions Asp --> Asn, Asp --> Lys, Asp --> Leu, show a correlation between diminished affinity for IL-2 receptor and reduced bioactivity measured on TS1beta cells. Mutein Asp Arg lose affinity for IL-2R and bioactivity simultaneously. Furthermore, during the course of the study we have found that mutein Asp20 --> Leu is an IL-2 antagonist. The biological effects of mAb H2-8 and the properties of new mutants at positions 17 and 20 demonstrate that this region of alpha helix-A is involved in IL-2-IL-2R beta interactions.

Biological and receptor-binding activities of human interleukin-2 mutated at residues 20Asp, 125Cys or 127Ser.

We have used site-directed mutagenesis to analyse structure-function relationships of the human Interleukin-2 molecule. The mutations introduced targetted residue 20Asp, within the N-terminal A helix, as well as residues 125Cys and 127Ser in the C-terminal D helix. The results presented here demonstrate that destabilizing the C-terminus alpha helix through introduction of Pro residues in either positions 125 or 127 reduced the biological activity of IL-2 by a factor of 10 that was correlated with a decreased ability to bind the receptor. A number of substitutions in position 20 have an even more drastic effect on biological activity and receptor binding. However, specific substitutions such as 20Asn and 20Leu displayed a differential effect on human or mouse IL-2 receptors. Furthermore, 20Leu IL-2 was found to behave as a partial antagonist of natural IL-2 when tested on murine cells.