Journal of Animal and Veterinary Advances
Year:
2010
Volume:
9
Issue:
4
Page No.
751 - 755
References
Baccari, G.C., S. Minucci, C. Marmorino and I.V. Izzo, 1991. Number of mast cells in the Harderian gland of the green frog,
Rana esculenta: The annual cycle and its relation to environmental and hormonal factors. J. Anat., 179: 75-83.
Bigaj, J., M. Urbanska-Stopa and B. Plyrycz, 1991. Argentaffin mast cells in the thymus of the frog. Folia Histochem. Cytobiol., 29: 45-47.
PubMed | Direct Link | Church, M.K. and F. Levi-Schaffer, 1997. The human mast cell. J. Allergy Clin. Immunol., 99: 155-160.
PubMed | Colombo, L.L., G.J. Chen, M.C. Lopez and R.R. Watson, 1992. Melatonin induced increase in gamma-interferon production by murine splenocytes. Immunol. Lett., 33: 123-126.
Crivellato, E., B. Nico, M. Battistig, C.A. Beltrami and D. Ribatti, 2005. The thymus is a site of mast cell development in chicken embryos. Anat. Embryol., 209: 243-249.
Direct Link | Dobrowsolska, A. and J. Gromadzka-Ostrowska, 1984. Age and androgen-related changes in morphological parameters, haematological parameters, level of serum proteins and glycoproteins, activity of the thyroid gland, suprarenals and kidneys in the common vole. J. Interdiscipl. Cycle Res., 5: 347-354.
Enerback, L., 1986. Mast Cell Heterogeneity: The Evolution of the Cconcept of a Specific Mucosal Mast Cell. In: Mast Cell Differentiation and Heterogeneity, Befus, A.D., J. Bienenstock and J.A. Denburg (Eds.). Raven Press, New York, pp: 1-26.
Galli, S.J., 1993. New concepts about the mast cell. New Engl. J. Med., 328: 257-265.
PubMed | Direct Link | Gurish, M. and K.F. Austen, 2001. The diverse role of mast cells. J. Exp. Med., 194: 1-5.
Hamaguchi, Y., Y. Kanakura, J. Fujita, S. Takeda and T. Nakano
et al., 1987. Interleukin 4 as an essential factor for in vitro clonal growth of murine connective tissue-type mast cells. J. Exp. Med., 165: 268-273.
Direct Link | Harma, R. and P. Soumalainen, 1951. Heparinocytes and hibernation in the Hedgehog. Acta Physiologica Scandinavica, 24: 90-95.
Irani, A.A., N.M. Schechter, S.S. Craig, G. De Blois and L.B. Schwartz, 1986. Two types of human mast cells that have distinct neutral protease compositions. Proc. Nat. Acad. Sci. USA., 83: 4464-4468.
Direct Link | Karaca, T., M. Yoruk and S. Uslu, 2006. Age-related changes in the number of mast cells in the Avian lymphoid organs. Anat. Histol. Embryol., 35: 375-379.
Kirshenbaum, A.S., J.P. Goff, T. Semere, B. Foster, L.M. Scott and D.D. Metcalfe, 1999. Demonstration that human mast cell arise from a progenitor cell population that is CD34(+), c-kit (+) and expresses aminopeptidase. Blood, 94: 2333-2342.
Direct Link | Kitamura, Y., S. Go and S. Hatanaka, 1978. Decrease of mast cells in W/Wv mice and their increase by bone marrow transplantation. Blood, 52: 447-452.
Klein, D.C., 1979. Circadian Rhythms in the Pineal Gland. In: Endocrine Rhythms, Krieger, D.T. (Ed.). Raven Press, New York, pp: 203-223.
Kliger, C.A., A.E. Gehad, R.M. Hulet, W.B. Roush, H.S. Lillehoj and M.M. Mashaly, 2000. Effects of photoperiod and melatonin on lymphocyte activities in male broiler chickens. Poult. Sci., 79: 18-25.
CrossRef | Direct Link | Konakchieva, R., S. Kyurkchiev, Iv. Kehayov, P. Taushanova and L. Kanchev, 1995. Selective effect of methoxyindoles on the lymphocyte proliferation and melatonin binding to activated human lymphoid cells. J. Neuroimmunol., 63: 125-132.
PubMed | Direct Link | Mahmoud, I., S.S. Salman and A. Al-Khateeb, 1994. Continuous darkness and continuous light induce structural changes in the rat thymus. J. Anat., 185: 143-149.
Majewski, P., I. Adamska, J. Pawlak, A. Barańska and K. Skwarło-Sońta, 2005. Seasonality of pineal gland activity and immune functions in chickens. J. Pineal Res., 39: 66-72.
CrossRef | PubMed | Direct Link | McNulty, J.A., M. Relfson, L.M. Fox, L.M. Fox, L. Kus, R.J. Handa and G.B. Schneider, 1990. Circadian analysis of mononuclear cells in the rat following pinealectomy and superior cervical ganglionectomy. Brain Behav. Immunol., 4: 292-307.
PubMed | Mekori, Y.A. and D.D. Metcalfe, 1999. Mast cell T-cell interactions. J. Allergy Clin. Immunol., 104: 517-523.
Moore, C.B. and T.D. Siopes, 2000. Effects of lighting conditions and melatonin supplementation on the cellular and humoral immune responses in Japanese quail
Coturnix coturnix japonica. Gen. Comp. Endocrinol., 119: 95-104.
CrossRef | Direct Link | Moore, C.B. and T.D. Siopes, 2003. Melatonin enhances cellular and humoral immune responses in the Japanese quail (
Coturnix coturnix japonica) via an opiatergic mechanism. Gen. Comp. Endocr., 131: 258-263.
Moore, C.B., T.D. Siopes, C.T. Steele and H. Underwood, 2002. Pineal melatonin secretion, but not ocular melatonin secretion, is sufficient to maintain normal immune responses in Japanese quail (
Coturnix coturnix japonica). Gen. Comp. Endocr., 126: 352-358.
Direct Link | Nelson, R.J. and G.E. Demas, 1996. Seasonal changes in immune function. Q. Rev. Biol., 71: 511-548.
Direct Link | Noviana, D., K. Mamba, S. Makimura and Y. Horii, 2004. Distribution, histochemical and enzyme histochemical characterization of mast cells in dogs. J. Mol. Histol., 35: 123-132.
Direct Link | Pioli, C., C. Caroleo, G. Nistico, G. Dorıa, 1993. Melatonin increases antigen presentation and amplifies specific and non specific signals for T-cell proliferation. Int. J. Immunopharmacol., 15: 463-468.
Direct Link | Shanahan, F., J.A. Denburg, J. Fox, J. Bienenstock and D. Befus, 1985. Mast cell heterogeneity: Effects of neuroenteric peptides on histamine release. J. Immunol., 135: 1331-1337.
Direct Link | Smith, D.E., Y.S. Lewis and G. Svihla, 1954. Blood clotting time and tissue mast cell number of the bat in different physiological states. Proc. Soc. Exp. Biol. Med., 86: 473-475.
PubMed | Direct Link | Smith, D.E., Y.S. Lewis and G. Svihla, 1954. Prolongation of clotting time in the dormant bat (
Myotis lucifugus). J. Cell. Mol. Life Sci., 10: 218-218.
CrossRef | Direct Link | Suomalainen, P. and R. Harma, 1951. Heparinocytes and hibernation. Experientia, 7: 380-380.
CrossRef | Direct Link |