This subproject is one of many research subprojects utilizing the resources provided by a Center grant funded by NIH/NCRR. The subproject and investigator (PI) may have received primary funding from another NIH source, and thus could be represented in other CRISP entries. The institution listed is for the Center, which is not necessarily the institution for the investigator. There has been no change in the scope of this project. It remains focused on the development of bispecific antibodies that can be tested for cell recruitment to sites of injury in skin and muscle. Bispecific antibodies (BiAbs) have drawn considerable attention from the research community. Their unique structure contains two distinct antigen-binding specificities, so they can be used for any application where it is desirable to juxtapose two molecules or cells within a distance of a few nanometers. For instance, a therapeutic agent can be placed on one arm, while the other is available to specifically target a diseased or injured tissue. This therapeutic agent can take many forms, including that of a toxin, drug, prodrug, enzyme, DNA, anti-vascular agent, gene therapy vector, radionucleotide or even a functional cell. Indeed, bispecific antibodies have been used in both research and clinical efforts to target cytotoxic T and NK cells to kill tumor cells. Considering recent advances in the identification of tissue-, disease-, and injury-specific antigens together with a better understanding in the fields of immunology and stem cell biology, BiAb technology holds great promise for addressing a number of therapeutic needs. The goal of this proposal is to take what we have learned from the application of BiAbs in targeting killer cells to tumors and demonstrate their broader potential in targeting a variety of cells to different injured tissues. These studies could have great therapeutic relevance to problems encountered in tissue repair. Moreover, establishing useful BiAb that can help recruit cells to the site of injury could increase our understanding of cell trafficking and the role of certain cell types, for example macrophages and bone marrow derived cells. We hypothesize that specific antibodies will direct trafficking of specific cell populations in different states of differentiation to sites of injury, where they can facilitate tissue repair and reconstitution. To test this hypothesis, we propose 1) to combine (chemically heteroconjugate) one mAb directed at an injury-associated antigen (i.e. fibrinopeptide A, VCAM-1, etc.) with a second mAb specific for an """"""""effector"""""""" cell population (i.e. F4/80 expressed by macrophages, c-kit expressed by bone marrow-derived stem cells, etc.) to produce a series of bispecific antibodies (BiAb), 2) to use these BiAbs to target these selected cell populations to injured skin and skeletal muscle tissues after experimentally-induced wounds in the respective mouse models (i.e. a full thickness tail-wound and a mechanical crush injury);and 3) to evaluate the effects of bispecific-antibody targeted cells on tissue repair and reconstitution. These studies will provide critical proof of the principle that the BiAbs can be used as a platform technology to specifically target cells to particular tissues. Based on these studies, a variety of mechanistic approaches and clinical applications in tissue repair are envisioned, limited only by the identification targeted cell- and injured tissue-specific antigens.

Agency
National Institute of Health (NIH)
Institute
National Center for Research Resources (NCRR)
Type
Exploratory Grants (P20)
Project #
5P20RR018757-08
Application #
8167641
Study Section
Special Emphasis Panel (ZRR1-RI-6 (01))
Project Start
2010-05-01
Project End
2011-04-30
Budget Start
2010-05-01
Budget End
2011-04-30
Support Year
8
Fiscal Year
2010
Total Cost
$220,362
Indirect Cost
Name
Roger Williams Hospital
Department
Type
DUNS #
625899281
City
Providence
State
RI
Country
United States
Zip Code
02908
Kim, Joseph W; Vang, Souriya; Luo, John Zq et al. (2017) Effects of bone marrow on the microenvironment of the human pancreatic islet: A Protein Profile Approach. Mol Cell Endocrinol 450:32-42
Tang, Jin Bo; Wu, Ya Fang; Cao, Yi et al. (2016) Basic FGF or VEGF gene therapy corrects insufficiency in the intrinsic healing capacity of tendons. Sci Rep 6:20643
Luo, John Z Q; Kim, Joseph W; Luo, LuGuang (2016) EFFECTS OF GINSENG AND ITS FOUR PURIFED GINSENOSIDES (Rb2, Re, Rg1, Rd) ON HUMAN PANCREATIC ISLET ? CELL IN VITRO. Eur J Pharm Med Res 3:110-119
Kim, Joseph W; Luo, John Z; Luo, Luguang (2015) The Biochemical Cascades of the Human Pancreatic ?-Cells: The Role of MicroRNAs. J Bioanal Biomed 7:
Luo, Lu Guang; Xiong, Fang; Ravassard, Philippe et al. (2015) Human Bone Marrow Subpopulations Sustain Human Islet Function and Viability In vitro. Br J Med Med Res 8:576-587
Ilgun, Handenur; Kim, Joseph William; Luo, LuGuang (2015) Adult Stem Cells and Diabetes Therapy. J Stem Cell Res Transplant 2:
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Chorzalska, A; Salloum, I; Shafqat, H et al. (2014) Low expression of Abelson interactor-1 is linked to acquired drug resistance in Bcr-Abl-induced leukemia. Leukemia 28:2165-77
Dabiri, Ganary; Falanga, Vincent (2013) Connective tissue ulcers. J Tissue Viability 22:92-102

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