Abstract

In this grant a murine model of lymphoproliferation will be analyzed to determine the molecular events involved in the clonal expansion of B-1 cells. The NZB strain develops clones of B-1 cells and is a model of chronic lymphocytic leukemia (CLL). Three different types of B-1 expanded populations will be studied: (1) pre-CLL in which the B-1 cells are expanded and several slow growing clones may be present, these appear in normal and (NZB, X DBA /2)Fl mice as late-appearing clones (2) CLL-like in which clonal expansion occurs and hyperdiploid B-1 clones develop which are non-aggressive, and (3) the expression of an aggressive invasive neoplasia of B-1 cells similar to that seen in Richter's. These three separate types of B-1 cells will be examined for both shared and unique characteristics which may be responsible for the clonal expansion. The B-1 clones will be analyzed for the ability to undergo apoptosis, a feature of fetal pre-B cells and a possible mechanism for the deletion of self-reactive cells and cells incapable of responding to a specific antigen. The possibility that apoptosis is increased in the early appearing B-1 hyperdiploid clones which develop into aggressive neoplasias and absent from the late appearing slow-growing clones may allow the possible use of apoptosis induction in the regulation of the growth of these neoplasias. The immunoglobulin sequence of the B-1 clones both early and late appearing will be studied. It is hypothesized that the neoplastic clones are similar to fetal B cells in the CDR3 region with very little N base substitutions. Molecular modeling studies will help to determine if developmental restrictions in the CDR3 region result in a unique binding site for the early appearing B-1 clones. Other characteristics of fetal B cells will be studied in the B-1 clones such as lambda 5 gene expression and cytokine expression. The role of IL-10 levels in both the development of B-1 neoplasias and the induction of apoptosis will be studied. Preliminary results have indicated that NZB mice that live nearly twice as long as the average life-span do not develop hyperdiploid B-1 malignancies but rather display T cell expansions. The cytokine profiles of these T cell clones will be studied as well as in vivo transfers of these T cells to determine the possible therapeutic role of T cells in the prevention of B-1 neoplasias. Finally, the genes responsible for the development of hyperdiploid B-1 clones will be investigated at a molecular level by two different techniques. The first technique will look for genetic polymorphisms in F2 and backcross animals which are linked to the expression of hyperdiploid B-1 clones. Another technique will use an mRNA subtraction library made up of the differences between slow and fast growing B-1 malignancies. The ultimate goal is to identify in the lymphoproliferative condition the genes responsible for the uncontrolled clonal expansion of B-1 neoplasias.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA071478-10
Application #
6124524
Study Section
Immunological Sciences Study Section (IMS)
Program Officer
Mccarthy, Susan A
Project Start
1989-09-30
Project End
2001-11-30
Budget Start
1999-12-01
Budget End
2001-11-30
Support Year
10
Fiscal Year
2000
Total Cost
$197,809
Indirect Cost

  Institution

Name
University of Medicine & Dentistry of NJ
Department
Pathology
Type
Schools of Medicine
DUNS #
623946217
City
Newark
State
NJ
Country
United States
Zip Code
07107

  Publications

Scaglione, Brian J; Salerno, Erica; Balan, Murugabaskar et al. (2007) Murine models of chronic lymphocytic leukaemia: role of microRNA-16 in the New Zealand Black mouse model. Br J Haematol 139:645-57
Raveche, Elizabeth S; Schutzer, Steven E; Fernandes, Helen et al. (2005) Evidence of Borrelia autoimmunity-induced component of Lyme carditis and arthritis. J Clin Microbiol 43:850-6
Czarneski, J; Lin, Y C; Chong, S et al. (2004) Studies in NZB IL-10 knockout mice of the requirement of IL-10 for progression of B-cell lymphoma. Leukemia 18:597-606
Yen Chong, S; Lin, Y C; Czarneski, J et al. (2001) Cell cycle effects of IL-10 on malignant B-1 cells. Genes Immun 2:239-47
Zhang, M; Chong, S Y; Raveche, E S (2001) The role of B-cell-specific activator protein in the response of malignant B-1 cells to LPS. Exp Cell Res 264:233-43
Chong, S Y; Zhang, M; Lin, Y C et al. (2001) The growth-regulatory role of B-cell-specific activator protein in NZB malignant B-1 cells. Cancer Immunol Immunother 50:41-50
Parker, G; Fernandes, H; Chong, S Y et al. (2000) Antisense IL-10 abrogates the inhibitory effects of IL-10 production by transfected tumor cells. Cytokines Cell Mol Ther 6:113-9
Czarneski, J; Lin, Y C; Ende, N et al. (1999) Effects of cord blood transfer on the hematopoietic recovery following sublethal irradiation in MRL lpr/lpr mice. Proc Soc Exp Biol Med 220:79-87
Peng, B; Zhang, M; Sun, R et al. (1998) The correlation of telomerase and IL-10 with leukemia transformation in a mouse model of chronic lymphocytic leukemia (CLL). Leuk Res 22:509-16
Zhang, M; Raveche, E S (1998) Apoptosis induction in fludarabine resistant malignant B-1 cells by G2-M cell cycle arrest. Oncol Rep 5:23-30

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