Drug – bio-affecting and body treating compositions – Designated organic active ingredient containing – Carbohydrate doai
Reexamination Certificate
2002-02-25
2003-10-07
Housel, James (Department: 1648)
Drug, bio-affecting and body treating compositions
Designated organic active ingredient containing
Carbohydrate doai
C514S002600, C514S004300, C514S012200, C800S286000, C800S285000, C536S023100, C536S023740, C536S023400, C435S005000
Reexamination Certificate
active
06630456
ABSTRACT:
FIELD OF THE INVENTION
The present invention, certain aspects of which are published in
Virus Research
(1999), 63:75-83 and
J. Virol.
(1999), 73:5056-5063 (which are herein incorporated by reference), relates to apoptosis in aquatic organisms induced by aquabimavirus, preferably infectious pancreatic necrosis virus (IPNV). It also relates to methods to regulate apoptosis in aquatic cells by controlling the expression of Mcl-1 gene and pre-treating the aquatic cells with drugs which block the viral replication. It further relates to a method for monitoring the progress of apoptosis using EGFP (a variant type of green fluorescent protein [GFP]) as a probe.
BACKGROUND OF THE INVENTION
Infectious pancreatic necrosis virus (IPNV) is an economically important fish pathogen. IPNV belongs to a group of viruses known as Birnaviridae (Brown (1986),
Intervirology,
25:141-143). Other members of Bimaviridae include infectious bursal disease virus (IBDV) of fowl and Drosophila X virus. IPNV was discovered to be associated with a highly contagious disease of susceptible hatchery-reared trout and salmonoids. As the name indicates, the infection among trout produces marked pancreatic necrosis, but histopathological changes sometimes also occur in adjacent adipose tissue, in renal hematopoietic tissue, in the gut, and in the liver (Wolf et al.(1960),
Proc. Soc. Exp. Biol. Med.,
104:105-108). Histopathological changes can also occur in renal excretory and hematopoietic tissues, as first reported by Yasutake et al. (1965),
Ann. N. Y. Acad. Sci.,
126:520-530. Although renal damage is consistent with the high titer of virus typically found in kidneys, at least in carrier fish, focal degeneration of liver parenchymal cells in yearling Atlantic salmon which had been previously inoculated with IPNV was also noted (Swanson and Gillespie (1979),
J. Fish. Res. Board Can.,
36:587-591).
IPNV shows a high degree of antigenic heterogeneity. Three different stereotypes, Ab, Sp and VR299 (MacDonald and Gower (1981),
Virology,
114:187-195; Okamoto et al. (1983),
Eur. J. Fish Dis.,
6:19-25) and ten subgroups (Heppell et al. (1992),
J. Gen. Virol.,
73:2863-2870) have been identified. IPNV is the etiological agent of a contagious, high mortality disease of young, hatchery-reared salmonids (Wolf et al. (1960), supra) and other non-salmonid fishes (Adair and Ferguson (1981),
J. Fish Dis.,
4:69-76). IPNV is a double-stranded RNA virus with four virion proteins (MacDonald and Dobos (1981),
Virology,
114:414-422).
Birnaviruses possess a bisegmented (A and B), double-stranded RNA genome contained within a medium-sized, unenveloped, icosahedral capsid. Birnavirus gene expression involves the production of four unrelated major genes that undergo various posttranslational cleavage to generate three to five structural proteins (Dobos, P. 1995. Annu. Rew. Fish Dis. 5, 25-54). The largest protein (90 kDa), VP1, is encoded by the smaller segment B genome, and the larger genome segment A encodes VP2 (42 kDa), VP4 (28 kDa) and VP3 (32 kDa). Genome segment A contains an additional small open reading frame (ORF) which overlaps the amino terminal end of the polyprotein from the reading frame (Duncan, R., Nagy, E., Krell, P. J. and Dobos, P. 1987. J. Virol. 61, 3655-3664). This small ORF encodes a 17 kDa arginine-rich minor polypeptide, VP5, which is produced in small quantities and is synthesized during the early replication cycle (Magyar, G. & Dobos, P. 1994. Virology 204, 580-589).
There are two major morphologically and biochemically distinct modes of death in eukaryotic cells: apoptosis and necrosis (Duvall and Wyllie (1986),
Immunol. Today,
7:115-119). Apoptosis is a physiological process involved in normal tissue turnover that occurs during embryogenesis, aging, and tumor regression, but pathological stimuli, such as viral infections (Gougeon and Montagnier (1993),
Science,
260:1269-1270), can also be triggering factors. Typically, apoptotic cell death is characterized by nuclear condensation, endonucleolytic degradation of DNA at nucleosomal intervals (“laddering”), and plasma membrane blebbing (Wyllie et al. (1980),
Int. Rev. Cytol.,
68:251-306). Necrosis is a pathological reaction that occurs in response to perturbations in the cellular environment such as complement attack, severe hypoxia, or hyperthermia. These stimuli increase the permeability of the plasma membrane, resulting in irreversible swelling of the cells (Wyllie et al,(1980), supra).
Apoptosis is important during embryonic development, metamorphosis, tissue renewal, hormone-induced tissue atrophy and many pathological conditions. In multi-cellular organisms, apoptosis ensures the elimination of superfluous cells including those that are generated in excess, have already completed their specific functions or are harmful to the whole organism. In reproductive tissues, massive cell death occurs under the control of hormonal signals. A growing body of evidence suggests that the intracellular “death program” activated during apoptosis is similar in different cell types and conserved during evolution. (Hengartner and Horvitz (1994),
Cell,
76:1107-1114). In addition to being essential for normal development and maintenance, apoptosis is important in the defense against viral infection and in preventing the emergence of cancer.
Apoptosis involves two essential steps. The “decision” step is controlled by the Bcl-2 family of proteins which consists of different anti- and pro-apoptotic members. The “execution” phase of apoptosis is mediated by the activation of caspases and cysteine proteases that induce cell death via the proteolytic cleavage of substrates vital for cellular homeostasis.
Bcl-2 protein is a 25 kD integral membrane protein of the mitochondria. Bcl-2 protein extends survival in many different cell types by inhibiting apoptosis elicited by a variety of death-inducing stimuli (Korsmeyer (1992),
Blood,
80:879-886). Overexpression of bcl-2 has been related to hyperplasia, autoimmunity and resistance to apoptosis (Fang et al. (1994),
J. Immunol.,
153:4388-4398). Bcl-2 contains a family of related genes, which includes, but is not limited to, A1, mcl-1, bcl-w, bax, bad, bak and bcl-x. A1, mcl-1, bcl-2 and bcl-x1 (long form of bcl-x) are presently known to confer protection against apoptosis and are referred to herein as “anti-apoptotic bcl-2 related proteins”. In contrast, bax, bad, bak and bcl-xs (short form of bcl-x) are presently known to promote cell death by inhibiting this protective effect.
Mcl-1 is one of the members of the Bcl-2 family. Like Bcl-2, Mcl-1 heterodimerizes with Bax, an accelerator of apoptosis in the Bcl-2 family, and neutralizes the cytotoxicity induced by Bax in yeast (Bodrug et al. (1996),
Death Differ.,
2:173-182). Mcl-1 is also able to protect Chinese hamster ovary cells from apoptosis induced by c-myc overexpression (Reynolds et al (1994),
Cancer Res.,
54:6348-6352). This protein was discovered as a novel gene induced early in the induction of differentiation of a human myeloid leukemia cell line (Kozopas et al. (1993),
Proc. Natl. Acad. Sci. USA,
90:3516-3520). Expression of Mcl-1 mRNA was rapidly up-regulated with phorbol ester in those cells followed by a rapid degradation, consistent with the presence of a mRNA destabilization sequence in its 3′-untranslated region. The half-life of the Mcl-1 protein is short (Yang et al. (1995),
J. Cell Biol.,
128:1173-1184), which has been ascribed to the presence of two PEST (proline, glutamic acid, serine, threonine) motifs. Therefore, Mcl-1 is suggested as a rapidly inducible, short-term effector of cell viability (Yang et al. (1996),
J. Cell. Physiol.,
166:523-536). Recently, Hong et al. (
Virology, (
1998), 250:76-84) reported that an El-S of IPNV Ab strain induced apoptosis in CHSE-214 cells. Hong et al.'s publication is herein incorporated by reference. In Hong et al.'s report, four kinds of detecting methods were used to determine whether apoptosis is involved in fish embryonic cell death after IPNV infection: (1) as
Hong Jiann-Ruey
Wu Jen-Leih
Academia Sinica
Chao Fei-Fei
Housel James
Li Bao Qun
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