University of Rochester School of Medicine
Xenopus laevis
Research Resource for Immunobiology funded by NIAID
Xenopus laevis References

Barritt, L.C. and Turpen, J.B. (1995).  Characterization of lineage restricted forms of Xenopus CD45 homologue.  Devel. Comp. Immunol.  19: 525-536.

Bleicher, P.A. and N. Cohen.  1981.  Monoclonal anti-IgM can separate T cell from B cell proliferative responses in the frog, Xenopus laevis.  J. Immunol.  127:1549-1555

Buscaglia, M. (1977).  Dissociation des déterminants des dévelopements gonadiques et somatiques au moment de la métamorphose chez Xenopus.  CR des Séances SPHN Genève 11: 53-58.

Chrétien, I., Robert, J., Marcuz, A., Garcia-Sanch, J, Courtet, M. and Du Pasquier L. (1996a).  Specific expression on cortical thymocytes of CTX a new polymorphic IgSF member.  Eur. J. Immunol. 26: 780-791.

Chrétien I, Marcuz A and L Du Pasquier (1996b). A ploidy marker to track lymphocytes after cells transfer between genetically identical or inbred.  In: Manual of Immunological Methods ed. I. Lefkovitz. Academic Press. pp. 2377.

Courtet, M., Flajnik, M., and Du Pasquier, L. (2001). Major histocompatibility complex and immunoglobulin loci visualized by in situ hybridization on Xenopus chromosomes. Dev Comp Immunol 25:149-57.

Du Pasquier, L., Flajnik, M. F., Guiet, C., and Hsu, E. (1985) Methods used to study the immune system of Xenopus (Amphibia, Anura). Immunol. Methods3:425-465

Du Pasquier, L., Schwager, J., and Flajnik, M. F. (1989).  The immune system of Xenopus.  Annu. Rev. Immunol. 7: 251-275.

Du Pasquier, L., Courtet, M. and Robert, J. (1995).  A Xenopus lymphoid tumor cell line with complete Ig genes rearrangements and T-cell characteristics.  Mol. Immunol. 32: 583-593.

Evans BJ, Kelley DB, Tinsley RC, Melnick DJ, Cannatella DC. (2004). A mitochondrial DNA phylogeny of African clawed frogs: phylogeography and implications for polyploid evolution. Mol Phylogenet Evol. 33:197-213.

Flajnik, M.F., Du Pasquier, L., and Cohen, N. (1985).  Immune responses of thymus/lymphocyte embryonic chimeras.  Studies on tolerance and MHC restriction in Xenopus.  Eur. J. Immunol.  15:540-547.

Flajnik, M.F., Hsu, E., Kaufman, J.F., and Du Pasquier, L. (1987).  Changes in the immune system during metamorphosis of Xenopus.  Immunol. Today.  8: 58-64.

Flajnik MF, Ferrone S, Cohen N, Du Pasquier L. (1990). Evolution of the MHC: antigenicity and unusual tissue distribution of Xenopus (frog) class II molecules. Mol Immunol. 27:451-462.

Flajnik, M. F., Taylor, E., Canel., C., Grossberger, D., and Du Pasquier, L. (1991). Reagents specific for MHC I antigens of Xenopus.  Amer. Zool. 31: 580-591.

Horton, J. D., Horton, T. L., Dzialo, R., Gravenor, I., Minter, R., Ritchie, P., Gartland, L, Watson, M. and Cooper, M. (1998).  T-cell and Natural killer cell development in thymectomized Xenopus. Immunol. Rev. 166:245-258.

Horton TL, Minter R, Stewart R, Ritchie P, Watson MD, Horton JD. (2000). Xenopus NK cells identified by novel monoclonal antibodies. Eur J Immuol. 30:604.

Hsu, E., and Du Pasquier, L. (1984).  Studies in Xenopus immunoglobulins using monoclonal antibodies.  Mol. Immunol. 21: 257-270

Hsu, E., (1998). Mutation, selection, and memory in B lymphocytes of exothermic vertebrates. Immunol. Rev. 162:25-36.

Ibrahim, B., Gartland, L.A., Kishimoto, T., Dzialo, R., Kubagawa, H., Bucy, R.P. and Cooper, M.D. (1991).  Analysis of T cell development in Xenopus.  Fed. Proc. 5: 7651.

Jürgens, J.B., Gartland, L.A., Kishimoto, T., Du Pasquier, L., Horton, J.D. and Cooper, M.D. (1995).  Identification of a candidate CD5 homologue in the amphibian Xenopus  laevis.  J. Immunol. 155: 4218-4223.

Kobel, H.R. and Du Pasquier, L. (1975).  Production of large clones of histocompatible, fully identical clawed toads (Xenopus).  Immunogenetics 2: 7-91.

Kobel HR, Egens De Sasso M, Zlotowski C. (1979). Developmental capacity of aneuploid Xenopus species hybrids .Differentiation.;14:51-8.

Kroll K and Amaya E. (1996). Transgenic Xenopus embryos from sperm nuclear transplantations reveal FGF signaling requirements during gastrulation. Development 122:3173-3183

Mussmann, R., Du Pasquier, L. and Hsu E. (1996). Is Xenopus IgX an analog of IgA? Eur. J. Immunol. 26: 2823-2830.

Nagata, S. (1985).  A cell surface marker of thymus dependent lymphocytes in Xenopus laevis is identified by mouse monoclonal antibody.  Eur. J. Immunol. 15: 837-841.

Nieuwkoop, P. D. and Faber, J. (1967).  Normal tables of Xenopus laevis (Daudin), North-Holland, Amsterdam.

Pollet N, Delius H, Niehrs C. (2003).  In situ analysis of gene expression in Xenopus embryos. C R Biol. 326:1011-1017.

Robert J, Guiet C and Du Pasquier L. (1994).  Lymphoid tumors of Xenopus laevis with different capacities for growth in larvae and adults.  Devel. Immunol. 3: 297.

Robert J and Du Pasquier L. (1997).  Xenopus lymphoid tumor cell lines.  In:  Manual of Immunological Methods ed. I. Lefkovitz. Academic Press, pp. 2367-2377.

Robert, J., Maniero, G., Cohen, N., and Gantress, J. (2004). Xenopus as an model system to study evolution of HSP-immune system interactions. In: Methods: A Companion to Methods in Enzymology (HSP-Immune System Interactions) Ed. P. Srivastava, Academic Press. Vol 32: 42-53.

Turpen JB. (1998). Induction and early development of the hematopoietic and immune systems in Xenopus.  Dev Comp Immunol. 22:265-278.

Turpen, J.B. (2004). Use of flow cytometry and combined DNA surface staining for analysis of hematopoietic development in the Xenopus embryo. Methods Mol Med. 105:159-170.