Chemistry: molecular biology and microbiology – Animal cell – per se ; composition thereof; process of...
Reexamination Certificate
2000-05-19
2003-07-15
Nashed, Nashaat T. (Department: 1652)
Chemistry: molecular biology and microbiology
Animal cell, per se ; composition thereof; process of...
C435S410000, C435S252300, C435S252330, C435S254110, C435S320100, C536S023100, C536S023600, C536S023400
Reexamination Certificate
active
06593135
ABSTRACT:
BACKGROUND OF THE INVENTION
Fluorescent molecules are attractive as reporter molecules in many assay systems because of their high sensitivity and ease of quantification. Recently, fluorescent proteins have been the focus of much attention because they can be produced in vivo by biological systems, and can be used to trace intracellular events without the need to be introduced into the cell through microinjection or permeablization. The green fluorescent protein of
Aequorea victoria
is particularly interesting as a fluorescent protein. A cDNA for the protein has been cloned. (D. C. Prasher et al., “Primary structure of the
Aequorea victoria
green-fluorescent protein,”
Gene
(1992) 111:229-33.) Not only can the primary amino acid sequence of the protein be expressed from the cDNA, but the expressed protein can fluoresce. This indicates that the protein can undergo the cyclization and oxidation believed to be necessary for fluorescence. Aequorea green fluorescent protein (“GFP”) is a stable, proteolysis-resistant single chain of 238 residues and has two absorption maxima at around 395 and 475 nm. The relative amplitudes of these two peaks is sensitive to environmental factors (W. W. Ward.
Bioluminescence and Chemiluminescence
(M. A. DeLuca and W. D. McElroy, eds) Academic Press pp. 235-242 (1981); W. W. Ward & S. H. Bokman
Biochemistry
21:4535-4540 (1982); W. W. Ward et al.
Photochem. Photobiol
. 35:803-808 (1982)) and illumination history (A. B. Cubitt et al.
Trends Biochem. Sci
. 20:448-455 (1995)), presumably reflecting two or more ground states. Excitation at the primary absorption peak of 395 nm yields an emission maximum at 508 nm with a quantum yield of 0.72-0.85 (O. Shimomura and F. H. Johnson
J. Cell. Comp. Physiol
. 59:223 (1962); J. G. Morin and J. W. Hastings,
J. Cell. Physiol
. 77:313 (1971); H. Morise et al.
Biochemistry
13:2656 (1974); W. W. Ward
Photochem. Photobiol. Reviews
(Smith, K. C. ed.) 4:1 (1979); A. B. Cubitt et al.
Trends Biochem. Sci
. 20:448-455 (1995); D. C. Prasher
Trends Genet
. 11:320-323 (1995); M. Chalfie
Photochem. Photobiol
. 62:651-656 (1995); W. W. Ward.
Bioluminescence and Chemiluminescence
(M. A. DeLuca and W. D. McElroy, eds) Academic Press pp. 235-242 (1981); W. W. Ward & S. H. Bokman
Biochemistry
21:4535-4540 (1982); W. W. Ward et al.
Photochem. Photobiol
. 35:803-808 (1982)). The fluorophore results from the autocatalytic cyclization of the polypeptide backbone between residues Ser
65
and Gly
67
and oxidation of the -&bgr; bond of Tyr
66
(A. B. Cubitt et al.
Trends Biochem. Sci
. 20:448-455 (1995); C. W. Cody et al.
Biochemistry
32:1212-1218 (1993); R. Heim et al.
Proc. Natl. Acad Sci
. USA 91:12501-12504 (1994)). Mutation of Ser
65
to Thr (S65T) simplifies the excitation spectrum to a single peak at 488 nm of enhanced amplitude (R. Heim et al.
Nature
373:664-665 (1995)), which no longer gives signs of conformational isomers (A. B. Cubitt et al.
Trends Biochem. Sci
. 20:448-455 (1995)).
Fluorescent proteins have been used as markers of gene expression, tracers of cell lineage and as fusion tags to monitor protein localization within living cells. (M. Chalfie et al., “Green fluorescent protein as a marker for gene expression,”
Science
263:802-805; A. B. Cubitt et al., “Understanding, improving and using green fluorescent proteins,” TIBS 20, November 1995, pp.448-455. U.S. Pat. No. 5,491,084, M. Chalfie and D. Prasher. Furthermore, engineered versions of Aequorea green fluorescent protein have been identified that exhibit altered fluorescence characteristics, including altered excitation and emission maxima, as well as excitation and emission spectra of different shapes. (R. Heim et al., “Wavelength mutations and posttranslational autoxidation of green fluorescent protein,”
Proc. Natl. Acad. Sci. USA
, (1994) 91:12501-04; R. Heim et al., “Improved green fluorescence,”
Nature
(1995) 373:663-665.)
A second class of applications rely on GFP as a specific indicator of some cellular property, and hence depend on the particular spectral characteristics of the variant employed. For recent reviews on GFP variants and their applications, see (Palm & Wlodawer, 1999; Tsien, 1998), and for a review volume on specialized applications, see (Sullivan & Kay, 1999). Biosensor applications include the use of differently colored GFPs for fluorescence resonance energy transfer (FRET) to monitor protein-protein interactions (Heim, 1999) or Ca2+ concentrations (Miyawaki et al., 1999), and receptor insertions within GFP surface loops to monitor ligand binding (Baird et al., 1999; Doi & Yanagawa, 1999).
The fluorescence emission of a number of variants is highly sensitive to the acidity of the environment (Elsliger et al., 1999; Wachter et al., 1998). Hence, one particularly successful application of green fluorescent protein (GFP) as a visual reporter in live cells has been the determination of organelle or cytosol pH (Kneen et al., 1998; Llopis et al., 1998; Miesenbock et al., 1998; Robey et al., 1998). The two chromophore charge states have been found to be relevant to the pH sensitivity of the intact protein, and have been characterized crystallographically in terms of conformational changes in the vicinity of the phenolic end (Elsliger et al., 1999), and spectroscopically using Raman studies (Bell et al., 2000). The neutral form of the chromophore, band A, absorbs around 400 nm in most variants, whereas the chromophore anion with the phenolic end deprotonated (band B) absorbs in the blue to green, depending on the particular mutations in the vicinity of the chromophore. WT GFP exhibits spectral characteristics that are consistent with two ground states characterized by a combination of bands A and B, the ratio of which is relatively invariant between pH 6 and 10 (Palm & Wlodawer, 1999; Ward et al., 1982). It has been suggested that an internal equilibrium exists where a proton is shared between the chromophore phenolate and the carboxylate of Glu222 over a broad range of pH (Brejc et al., 1997; Palm et al., 1997). Recent electrostatic calculations support this model (Scharnagl et al., 1999), and estimate the theoretical pK
a
for complete chromophore deprotonation to be about 13, consistent with the observation of a doubling of emission intensity at pH 11-12 (Bokman & Ward, 1981; Palm & Wlodawer, 1999).
In contrast to WT GFP, the chromophore of most variants titrates with a single pK
a
. The color emission and the chromophore pK
a
are strongly modulated by the protein surroundings (Llopis et al., 1998). Glu222 is completely conserved among GFP homologs (Matz et al., 1999), and its substitution by a glutamine has been shown to dramatically reduce efficiency of chromophore generation (Elsliger et al., 1999). Protonation of Glu222 in S65T and in GFPs containing the T203Y mutation (YFPs) is generally thought to be responsible for lowering the chromophore pKa from that of WT to about 5.9 in GFP S65T (Elsliger et al., 1999; Kneen et al., 1998), and 5.2-5.4 in YFP (GFP S65G/V68L/S72A/T203Y) (Ormo et al., 1996; Wachter & Remington, 1999). In the YFPs, it is thought that the crystallographically identified stacking interaction of the chromophore with Tyr203 is largely responsible for the spectral red-shift (Wachter et al., 1998).
Unlike other variants, we have discovered that the YFP chromophore pK
a
shows a strong dependence on the concentration of certain small anions such as chloride (Wachter & Remington, 1999), and increases in pK
a
from about 5.2 to 7.0 in the presence of 140 mM NaCl (Elsliger et al., 1999). This sensitivity can be exploited to enable the creation of novel GFPs as biosensors to measure ions present both in the cytoplasm or in cellular compartments (Wachter & Remington, 1999) within living cells. The present invention includes the creation and use of novel GFP variants that permit the fluorescent measurement of a variety of ions, including halides such as chloride and iodide. These properties add variety and utility to the arsenal of biologically based fluorescent indicators. There is a need for
Remington S. James
Wachter Rebekka M.
Gray Cary Ware & Freidenrich LLP
Haile Lisa A.
Nashed Nashaat T.
The State of Oregon, Acting by and Through the State Board of Hi
LandOfFree
Long wavelength engineered fluorescent proteins does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Long wavelength engineered fluorescent proteins, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Long wavelength engineered fluorescent proteins will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3107578