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Description  |
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FIELD OF THE INVENTION
This invention relates to a method for time-resolved fluorimetric detection
of fluorescent labeled nucleotides in a gel electrophoresis system in
which there is used as fluorescent labeled nucleotides, nucleotides
conjugated with a chelating agent and labeled with a lanthanide.
BACKGROUND OF THE INVENTION
The ability to detect nucleic acids or nucleotides at trace levels is
required and extremely important in many areas of biotechnology. In the
past, tracking and detection of nucleotides was usually performed using
radioisotopes. However, these methods employing radioisotopes are
generally very laborious, time-consuming, expensive, and require the use
of unstable and hazardous radioisotopes leading to problems and handling
and disposal of the radioisotope labeled reagents. Therefore, interest has
arisen in discovering alternative and safer methods of detection.
One such alternative has been the suggestion that enzyme catalyzed color
development be employed However, this proposed methodology has not found
general acceptance because of a much lowered sensitivity than methods
employing radiolabeled nucleotides In addition, the enzyme catalyzed
methodology was found not to have any general improved ease of performance
over the radiolabeled nucleotide methods.
Therefore, as another alternative, various methods of detecting nucleic
acids or nucleotides based upon fluorescent emissions have been proposed
or employed. Perhaps the most widely employed method involves staining
with a dye such as ethidium bromide. However, due to background emission
from unbound dye, the detection limits cannot approach those in
autoradiography. It has been proposed that elimination of the background
problem due to free dye can be achieved by covalent modification of
nucleic acid with a fluorescent tag followed by separation of unreacted
label. With appropriate choice of fluorophore and optimization of the
optical train, sensitivities approaching or matching those of
radioisotopic detection are considered to be possible Several research
groups have employed this approach to detect DNA fragments in
polyacrylamide gels. A drawback of this approach is that the gel is a
source of significant scattering and background fluorescence.
An alternative detection scheme which is theoretically more sensitive than
autoradiography is time-resolved fluorimetry. According to this method, a
chelated lanthanide metal with a long radiative lifetime is attached to
the molecule of interest. Pulsed excitation combined with a gated
detection system allows for effective discrimination against short-lived
background emission Syvanen et al., Nucleic Acids Research, 14, 1017-1028
(1986) have demonstrated the utility of this approach for quantifying DNA
hybrids via an europium-labeled antibody. In addition, biotinylated DNA
was measured in microtiter wells using Eu-labeled strepavidin as reported
by P. Dahlen, Anal. Biochem , 164, 78-83 (1982). However, a disadvantage
of these types of assays is that the label must be washed from the probe
and its fluorescence developed in an enhancement solution. In addition, it
has been difficult to provide sufficiently stable labeled molecules to
provide for acceptable detection thereof. Moreover, in gel electrophoresis
systems the labeled molecules have generally not provided sufficient
stability on dilution or when subjected to the elevated temperatures of
the gel electrophoresis to enable acceptable detection of the labeled
molecules. A further drawback has been the fact that the fluorescence
produced has only been in the nanosecond (ns) range, a generally
unacceptably short period for adequate detection of the labeled molecules
and for discrimination from background fluorescence.
Thus, a need has clearly arisen for fluorescent labeled nucleotides that
can be employed in gel electrophoresis systems to provide long lived
fluorescence to avoid background fluorescence by use of an intermittent
excitation source and a timed coupled measurement of fluorescence. A still
further need is to provide for such fluorescent labeled nucleotides for
use in detecting nucleotides by time-resolved fluorimetric determination
of such labeled nucleotides separated in a gel electrophoresis system in
which the labeled nucleotide remains stable and detection limits are
significantly improved in comparison to covalent labels with fluorescent
lifetimes in the nanosecond range or in comparison to such system
employing stains such as ethidium bromide A further need is to provide
such a detection method in which the fluorescent labeled nucleotide
remains stable and fluorescent upon dilution in the gel system and in an
electric field at an elevated temperature of about 60.degree. C. A still
further need is to provide such a method for such time-resolved
fluorimetric detection of labeled nucleotides in gel electrophoresis
systems in which no enhancement solution is required for detection and
thereby permitting on-line detection of the fluorescent labeled
nucleotides.
SUMMARY OF THE INVENTION
A method for time-resolved fluorimetric detection of fluorescent labeled
nucleotides monomers, oligomers or polymers separated in a gel
electrophoresis system is provided by employing as the fluorescent labeled
nucleotides lanthanide chelate labeled covalent nucleotide conjugates. The
invention further provides such a method for on-line time-resolved
fluorimetric detection of such fluorescent labeled nucleotides separated
in gel electrophoresis systems.
DETAILED DESCRIPTION OF THE INVENTION
In accordance with this invention, time-resolved fluorimetric detection of
fluorescent labeled nucleotides separated in a gel electrophoresis system
is provided by employing a lanthanide chelate labeled covalent nucleotide
conjugate in which the nucleotide may be a monomer, oligomer of polymer of
either DNA or RNA, although for purposes of illustrating the invention the
following examples and discussion relate to DNA nucleotides.
The lanthanide chelate labeled covalent nucleotide conjugates useful in the
invention may be the chelate of any suitable lanthanide producing the
stable lanthanide chelate of a covalent nucleotide conjugate having the
properties previously described. While any suitable lanthanide chelate may
be employed, it is preferred that the lanthanide be terbium, samarium,
europium, dysprosium or neodymium, with terbium being the especially
preferred lanthanide moiety.
The lanthanide is chelated to a nucleotide which has been covalently
reacted with a strong lanthanide chelating agent. The chelating agent
which is reacted with the nucleotide is any suitable chelating agent that
is capable of covalently binding to a reactive group on a nucleotide and
which also chelates to a fluorescent lanthanide in a stable manner so that
a long-lived lanthanide chelate of the covalently bound
nucleotide-chelating agent conjugate is provided. By long-lived
fluorescence is meant a high quantum yield fluorescence that is not
appreciably decayed when background interference has already decayed. It
is also desirable that the chelating agent does not adversely affect the
ability of the nucleotide to undergo hybridization.
As examples of chelating agents suitable for reaction with nucleotides to
form the nucleotide conjugates suitable for chelating lanthanides, there
may be mentioned, for example, amine polyacids, cryptands, polyacid
substituted pyridine derivatives and the like. As examples of each
chelating agents, there may be mentioned, for example, amine polyacids
such as diethylenetriaminepentaacetic acid dianhydride (DTPAA),
benzenediazonium ethylenediaminetetraacetic acid (EDTA), cryptands such as
isothiocyanatobenzyl 2B:2:1 cryptand, and polyacid substituted pyridine
derivatives such as 2,6-bis[N,N-Di(carboxymethyl)aminomethyl]-4
-(3-isothiocyanatophenyl)-pyridine tetraacid. Especially preferred as the
chelating agent is DTPAA.
The chelating agent is preferably covalently bound to the nucleotide along
with an energy transfer agent, preferably an aminoaromatic compound such
as, for example, p-aminosalicylic acid (pAS), aminophenazone,
aminomethylsalicylic acid, aniline, aminophthalic acid,
3,4-dihydroxybenzylamine, 5-aminoisophthalic acid, 5-aminophenanthroline,
3-aminobenzoic acid and the like. Preferably pAS is employed as the energy
transfer moiety.
Preferably, the nucleotide conjugate to which the lanthanide is chelated is
a conjugate of the formula:
Nuc-N*-Y-Z
wherein Nuc is a nucleotide monomer, oligomer or polymer, N* is an amine
nitrogen either intrinsic to the nucleotide or extrinsinc and introduced
as a label prior to conjugation, Y is a chelating group capable of
chelating a lanthanide and Z is an energy transfer moiety More preferably
Y is a diethylenetriaminepentaacetic acid group and Z is a
p-aminosalicylate moiety and thus the conjugate has the formula:
##STR1##
Especially preferred lanthanide chelate labeled nucleotide conjugates used
in the methods of this invention are terbium chelates of
nucleotide-DTPAA-pAS conjugates.
The lanthanide labeled nucleotide conjugates employed in this invention are
highly fluorescent labeled conjugates with lifetime in the microsecond
(ms) range. Thus, when a pulsed source and gated electronics are employed,
the long-lived fluorescence decay permits effective discrimination against
background fluorescence, stray light and scattered excitation.
Furthermore, such lanthanide labeled nucleotide conjugates are very stable
and maintain their integrity in electrophoretic gel systems and maintain
their fluorescent properties upon dilution and in an electric field at
elevated temperatures of about 60.degree. C., conditions typically
encountered during polyacrylamide gel electrophoresis. Moreover, such
lanthanide labeled covalent nucleotide conjugates do not require
enhancement solutions for detection and therefore the detection
methodology may be used in situations where on-line detection is desirable
or required. Since the methodology of this invention permits on-line
detection of the fluorescent labeled nucleotides conjugates, the method
can be employed in gel electrophoresis system for the purpose of DNA or
RNA sequence determination according to the procedures of Maxam-Gilbert or
Sanger, or for restriction mapping or other procedures where detection of
nucleic acids is required. In addition to all of the above-mentioned
advantages, the lanthanide chelates of the covalent nucleotide conjugates
permit the elimination of the use of radioisotopes in the gel
electrophoresis system yet provides a nucleotide detection methodology
that rivals the sensitivity obtained when using radioisotope labeled
nucleotides.
The invention is demonstrated by the following illustrative examples.
PREPARATION OF LANTHANIDE CHELATE LABELED NUCLEOTIDE CONJUGATES
Sodium pAS was dried overnight at 110.degree. C. and solutions of the
sodium pAS and DTPAA were prepared in dry DMSO at 0.1 M; equimolar
triethylamine was added to the DTPAA solution to facilitate dissolution.
An equal volume of the pAS solution was added dropwise to the DTPAA
solution followed by stirring for about 60 minutes to produce a conjugate
reaction mixture or chelating agent.
Separately, plasmid pBR322 was purified by centrifugation on a cesium
chloride-ethidium bromide gradient and the plasmid then cleaved with HinfI
restriction enzyme to produce a plasmid digest according to procedures
known in the art and as described by T. Mamatis et al., Molecular Cloning:
A Laboratory Manual, 100-106, Cold Spring Harbor Laboratory, Cold Spring
Harbor, N.Y. HinfI digestion of pBR322 generates 10 fragments with
staggered ends ranging from 75 base pairs to 1631 base pairs; the sequence
of single-stranded bases at each end is ANT, where N denotes any
nucleotide. It is assumed that the exocycle amines on the exposed bases
provide sites for attack by the monoanhydride adduct, forming an amide
linkage.
Seven uL of the conjugate reaction mixture was added to 150 .mu.L of the
plasmid digest (0.145 .mu.g/.mu.L cleaved pBR322) and stirred at room
temperature for about 60 min. After storage overnight at 4.degree. C., 6.8
.mu.L of 0.05 M terbium chloride was added, the mixture was shaken and let
stand for about 30 min. Excess, hydrolyzed chelate was separated from the
plasmid digest chelate conjugate by two passes through a 16.times.1 cm
column packed with Sephadex G 25-150. The elution buffer was 10 mM
3-[N-morpholino]propane sulfonic acid (MOPS) pH 7.0 After each
purification, the DNA-containing fractions were pooled and evaporated to
dryness under vacuum to produce the terbium labeled nucleotide conjugate.
CHARACTERIZATION OF TERBIUM LABELED DNA CONJUGATE
DNA concentration of the labeled DNA conjugate was determined by
measurement of absorbencies at 260 nm. Label concentration was determined
by comparing the fluorescence of the purified labeled nucleotide conjugate
with the fluorescence of free chelate, i.e. diethylenetriaminepentaacetic
acid dianhydride p-aminosalicylate adduct (DTPAA-pAS) complexed with
terbium. The assumption inherent in this method is that the quantum yield
of the conjugated label is equal to the free chelate. Correction for pAS
absorption at 260 nm when measuring DNA concentration was not necessary
due to the low pAS/base ratio. Spectral measurements were performed with a
Perkin-Elmer Lambda Array UV-VIS spectrometer and a Perkin-Elmer LS-5
spectrofluorimeter; the latter employs a pulsed source and gated detection
electronics, permitting selective observation of delayed emission. Samples
were excited at 260 nm and detected at 545 nm using 10 nm slits; the delay
between excitation and detection was 0.1 ms while the gate was 6 ms.
The extent of chelate incorporation into the purified DNA conjugate was
calculated to be 6.3 pmol per ug of DNA.
The quantum yield of the free chelate was estimated using the relation
##EQU1##
where Q.sub.c and Q.sub.qs are the quantum yields of the free chelate and
quinine sulfate, respectively; F.sub.c and F.sub.qs are the areas under
the corrected emission spectra; and A.sub.c and A.sub.qs are the
absorbances at the respective excitation wavelengths. Q.sub.qs was taken
as 0.59 at 347 nm excitation. Quinine sulfate fluorescence was measured
without a time delay between excitation and detection while free chelate
fluorescence was measured with the delay and gate settings listed above.
Although measurement of standard and sample emission under different
instrumental conditions affects the accuracy of the estimated Q.sub.c,
this prevented calculating an artificially low value due to the delayed
fluorescence of the label.
Lifetimes were determined by measuring the emission intensity as a function
of the time delay between excitation and detection, holding the gate
constant. The data were fit to the best single exponential of the form
I=I.sub.o e.sup.-kt.
The emission spectra of the purified terbium labeled nucleotide conjugate
is characteristic of the terbium ion, with the maximum intensity occurring
at 545 nm. The excitation spectrum closely matches the absorption spectrum
of pAS consistent with the understanding that the terbium emission is not
excited directly but is due to energy transfer from the salicylate group.
At the concentrations employed, terbium fluorescence could not be detected
in the absence of the DTPAA-pAS adduct. Detection was also not possible in
the presence of pAS and hydrolyzed DTPAA (no adduct formation).
The quantum yield of the free chelate was estimated to be 0.09 at room
temperature, which is appreciable for such a long-lived fluorophore; the
molar absorptivity is 17900 M.sup.-1 cm.sup.-1 at 260 nm. It is assumed
that the spectral properties of the free chelate are similar to that of
the chelate coupled to DNA since the excitation and emission spectra are
substantially identical. Time-resolved emission measurements of the free
chelate and the DNA-chelate conjugate yielded fluorescence lifetimes of
1.7 and 1.5 ms, respectively. Thus, when gated electronics are employed to
discriminate against short-lived scattering and background fluorescence,
detection of the chelate will be possible at very low levels. An emission
scan (60 nm/min) of a 1 nM solution of the free chelate using the standard
conditions listed above gave a signal-to-noise ratio of 64 at 545 nm.
GEL ELECTROPHORESIS AND TERBIUM LABELED NUCLEOTIDE CONJUGATE DETECTION
The terbium labeled nucleotide conjugates (labeled restriction fragments)
prepared according to the foregoing described preparation were
electrophoresed on a 1.5 mm.times.16 cm, 5% polyacrylamide gel in pH 8.0
Tris-borate buffer (0.089 M, without EDTA). The polyacrylamide gel was of
the following formulation:
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40 ml Deionized Water
4.81 g Acrylamide
0.17 g Bis-acrylamide
42 g Urea
10 ml 10X Sequencing Buffer*
0.66 ml 10% Ammonium Persulfate
0.060 ml TEMED
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Deionized Water to 100 mls
*10X Sequencing Buffer 500 mM Tris Base, 500 mM Boric Acid.
The system was run at 8 V/cm until the bromophenol blue tracking dye was
approximately 2 cm from the bottom of the gel. The gel was then removed
from the apparatus and transilluminated (Fotodyne, Model 3-3000) to locate
the labeled DNA fragments. The portions of gel containing the
DTPAA-pAS-Tb-labeled DNA plasmid digest, identified by the characteristic
green emission, were cut out of the gel and placed individually in
centrifuge tubes with 1 mL of deionized water. After storage at 4.degree.
C. for 6 days, the supernatants were separated from the gel fragments,
diluted up to a final volume of 1.5 mL, and assayed for chelate emission.
The time-resolved fluorescence intensity of the gel extracts was measured
on a Perkin-Elmer Model LS-5 spectrofluorimeter under the following
conditions: slit widths, 10 nm; excitation wavelength, 260 nm; emission
wavelength, 545 nm; time delay from excitation to observation, 0.1 ms;
duration of observation gate, 6 ms. All extracts were diluted to a final
volume of 1.5 mL before measurement. The absolute intensity values
recorded for the eight fractions of the gel (labeled restriction fragments
were extracted from eight pieces of the gel) are listed in the following
table. The order of the fractions is from least mobile (top of the gel) to
most mobile (bottom of the gel).
TABLE I
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Fluorescence Intensity
Gel Fraction
(absolute intensity value)
pmol of Label
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1 47.7 18.9
2 51.5 16.6
3 43.9 8.2
4 41.4 5.2
5 45.3 9.8
6 4.7 9.1
7 42.0 5.9
8 37.9 1.1
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The measured fluorescence intensity values were converted to the amounts of
the fluorescent label, DTPAA-pAS-Tb, attached to pBR322 restriction
fragments in each gel fraction through a calibration curve. The
calibration curves was constructed by measuring the fluorescence intensity
from serial dilutions of the hydrolyzed adduct complexed with terbium
(free chelate) under the same instrumental conditions as the labeled
restriction fragments. The results of those measurements are shown in the
following Table II.
TABLE II
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Free Chelate (nmol/liter)
Fluorescence Intensity
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0 37.0
8.33 43.8
16.67 51.3
25.00 58.5
33.33 65.2
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These data were plotted and fit by a least squares algorithm to a line
described by the equation fluorescence intensity
=36.94+0.8532.times.concentration (in nmol/liter). The equation allows the
conversion of the intensity values in Table I to concentrations. For
example, gel fraction 1 contains 47.7 -36.94/0.8532=12.6 nmol/liter of the
label attached to pBR322 fragments. The volume of each gel extract was
0.0015 liter. Therefore, the amount of label attached to pBR322 fragments
in fraction 1 is 12.6 nmol/liter.times.0.0015 liter=0.0189 nmol or 18.9
pmol. The amount for each gel fraction is set forth in the third column of
Table I above.
The mass of labeled restriction fragments applied to the gel was 20.7
.mu.g. Characterization of the labeled restriction fragments prior to
electrophoresis showed that this mass of DNA carried 130 pmol of
fluorescence label. Summing column 3 in Table I reveals that 74.8 pmol of
label were recovered from the gel by the extraction procedure. Therefore,
the percentage of label (and DNA) recovered from the gel is 100
.times.74.8 pmol/130 pmol=58%.
STABILITY OF LABELED DNA FRAGMENTS SUBJECTED TO POLYACRYLAMIDE GEL
ELECTROPHORESIS
The Tb-labeled double stranded DNA fragments were subjected to
polyacrylamide gel electrophoresis to determine if the integrity of the
conjugated complex could be maintained at elevated temperature in an
electric field. Transillumination of the gel at room temperature after
polyacrylamide gel electrophoresis permitted visualization of the
characteristic green emission of the conjugated DNA. The DNA bands were
extracted from the gel in the same manner as previously described and the
chelate content was quantified by time-resolved fluorimetry. The total
fluorescence recovered from the gel corresponded to 75 pmol of chelate (12
.mu.g of DNA), representing 58% of the amount applied to the gel.
The effect of temperature on the quantum efficiency of the free DTPAA-pAS
chelate was examined in a separate experiment. DTPAA-pAS-Tb was added to
an 8% polyacrylamide gel before polymerization; crosslinking was allowed
to take place in a standard 1 cm quartz cuvet. Fluorescence spectra
acquired with the cuvet thermostated at 25.degree. C. and 60.degree. C.
showed that 20% of the fluorescence intensity of the free chelate was
retained with the temperature increase and said fluorescence remained
detectable.
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