技术资料

Injury induces the recruitment of bone marrow-derived cells (BMDCs) that contribute to the repair and regeneration process. The behavior of BMDCs in injured tissue has a profound effect on repair,but the regulation of BMDC behavior is poorly understood. Aberrant recruitment/retention of these cells in wounds of diabetic patients and animal models is associated with chronic inflammation and impaired healing. BMD Gr-1(+)CD11b(+) cells function as immune suppressor cells and contribute significantly to tumor-induced neovascularization. Here we report that Gr-1(+)CD11b(+) cells also contribute to injury-induced neovascularization,but show altered recruitment/retention kinetics in the diabetic environment. Moreover,diabetic-derived Gr-1(+)CD11b(+) cells fail to stimulate neovascularization in vivo and have aberrant proliferative,chemotaxis,adhesion,and differentiation potential. Previously we demonstrated that gene transfer of HOXA3 to wounds of diabetic mice is taken up by and expressed by recruited BMDCs. This is associated with a suppressed inflammatory response,enhanced neovascularization,and accelerated wound healing. Here we show that sustained expression of Hoxa3 in diabetic-derived BMD Gr-1(+)CD11b(+) cells reverses their diabetic phenotype. These findings demonstrate that manipulation of adult stem/progenitor cells ex vivo could be used as a potential therapy in patients with impaired wound healing. View Publication

The cytidine deaminase AID (encoded by Aicda in mice and AICDA in humans) is critical for immunoglobulin class-switch recombination (CSR) and somatic hypermutation (SHM). Here we show that AID expression was induced by the HoxC4 homeodomain transcription factor,which bound to a highly conserved HoxC4-Oct site in the Aicda or AICDA promoter. This site functioned in synergy with a conserved binding site for the transcription factors Sp1,Sp3 and NF-kappaB. HoxC4 was 'preferentially' expressed in germinal center B cells and was upregulated by engagement of CD40 by CD154,as well as by lipopolysaccharide and interleukin 4. HoxC4 deficiency resulted in impaired CSR and SHM because of lower AID expression and not some other putative HoxC4-dependent activity. Enforced expression of AID in Hoxc4(-/-) B cells fully restored CSR. Thus,HoxC4 directly activates the Aicda promoter,thereby inducing AID expression,CSR and SHM. View Publication

To evaluate the role of the TCR in the alphabeta/gammadelta lineage choice during human thymocyte development,molecular analyses of the TCRbeta locus in gammadelta cells and the TCRgamma and delta loci in alphabeta cells were undertaken. TCRbeta variable gene segments remained largely in germline configuration in gammadelta cells,indicating that commitment to the gammadelta lineage occurred before complete TCRbeta rearrangements in most cases. The few TCRbeta rearrangements detected were primarily out-of-frame,suggesting that productive TCRbeta rearrangements diverted cells away from the gammadelta lineage. In contrast,in alphabeta cells,the TCRgamma locus was almost completely rearranged with a random productivity profile; the TCRdelta locus contained primarily nonproductive rearrangements. Productive gamma rearrangements were,however,depleted compared with preselected cells. Productive TCRgamma and delta rearrangements rarely occurred in the same cell,suggesting that alphabeta cells developed from cells unable to produce a functional gammadelta TCR. Intracellular TCRbeta expression correlated with the up-regulation of CD4 and concomitant down-regulation of CD34,and plateaued at the early double positive stage. Surprisingly,however,some early double positive thymocytes retained gammadelta potential in culture. We present a model for human thymopoiesis which includes gammadelta development as a default pathway,an instructional role for the TCR in the alphabeta/gammadelta lineage choice,and a prolonged developmental window for beta selection and gammadelta lineage commitment. Aspects that differ from the mouse are the status of TCR gene rearrangements at the nonexpressed loci,the timing of beta selection,and maintenance of gammadelta potential through the early double positive stage of development. View Publication

Current strategies for the production of therapeutic mAbs include the use of mammalian cell systems to recombinantly produce Abs derived from mice bearing human Ig transgenes,humanization of rodent Abs,or phage libraries. Generation of hybridomas secreting human mAbs has been previously reported; however,this approach has not been fully exploited for immunotherapy development. We previously reported the use of transient regulation of cellular DNA mismatch repair processes to enhance traits (e.g.,affinity and titers) of mAb-producing cell lines,including hybridomas. We reasoned that this process,named morphogenics,could be used to improve suboptimal hybridoma cells generated by means of ex vivo immunization and immortalization of antigen-specific human B cells for therapeutic Ab development. Here we present a platform process that combines hybridoma and morphogenics technologies for the generation of fully human mAbs specific for disease-associated human antigens. We were able to generate hybridoma lines secreting mAbs with high binding specificity and biological activity. One mAb with strong neutralizing activity against human granulocyte-macrophage colony-stimulating factor was identified that is now considered for preclinical development for autoimmune disease indications. Moreover,these hybridoma cells have proven suitable for genetic optimization using the morphogenics process and have shown potential for large-scale manufacturing. View Publication