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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a method for discriminating a kind of nucleic
acid bases of DNA.
2. Related Background Art
As shown in FIGS. 1A-1D, DNA (deoxyribonucleic acid) is a copolymer of four
kinds of deoxynucleotides, which are shown in FIGS. 2A-2D, i.e.,
deoxyadenylic acid (shown in FIG. 1A), deoxyguanylic acid (shown in FIG.
1B), deoxythymidylic acid (shown in FIG. 1C), and deoxycytidylic acid
(shown in FIG. 1D). These deoxynucleotides have at the base sites of their
respective deoxyriboses an adenine, a guanine, a thymine, or a cytosine,
which are nucleic acid bases. A sequence of these deoxynucleotides is
intrinsic to a gene.
Conventionally in sequencing these deoxynucleotides, a DNA chain is labeled
using a radioactive isotope (R.I.) or a fluorescent dye. The conventional
method is disclosed in U.S. Pat. No. 4,962,037. But this method needs a
preparatory treatment of separately adding a fluorescent dye, etc.
In view of this, discriminating methods using the chromophores of DNA are
used. As a typical example of these methods, a method using a solution of
DNA in a water/methanol solvent with a ratio of 1:1 is described in "Basic
Principles in Nucleic Acid Chemistry", Vol. I, Academic Press (1974), p.
322.about.328. In this method, a temperature of this solution is lowered
to 77K, and then UV laser beams are irradiated to the sample solution by a
secondary higher harmonic generator. By these laser beams directed to
electrons of the respective chromophores of A (adenine), T (thymine), G
(guanine), C (cytosine), four kinds of nucleic acid bases of each of DNAs
are discriminated from each molecule flowing one after another in the
above-mentioned solution. The reference discloses that the irradiation of
laser beams as excitation light at a temperature below room temperature
much improves quantum yields of the nucleic acid bases in comparison with
yields at room temperature.
The solvent comprises a the mixture of water and methanol because, when
water is used alone, cubical expansions of the water take place at low
temperatures, breaking the container. Usually alcohol is added to water
for the prevention of volume expansion at low temperatures, and,
additionally, causes the solvent to be transparent and vitreous.
FIGS. 3A-3D show spectra of the fluorescence and phosphorescence emitted
from the solution using the above-described method in A, T, G and C,
respectively. As shown, all the nucleic acid bases have peaks of
fluorescence near a wavelength of 325 nm. A and G have spectra having high
peaks near 400 nm. These are phosphorescence spectra, and the lifetimes of
the respective phosphorescence are of A and G 2.7 seconds, and 1.6
seconds. By their respective phosphorescence lifetimes, A and G can be
discriminated from each other. T and C, which emit no phosphorescence, are
measured in terms of lifetimes of fluorescence. FIG. 10 shows the
lifetimes of fluorescence of the four kinds of nucleic acid bases. In
FIGS. 4A-4D, fluorescence intensity is taken on the vertical axis, and
lifetime of fluorescence is taken on the horizontal axis. 1 ch on the
horizontal axis is equal to 77 psce. The sharp peaks around 100 ch show
excitation light, and the blunt extinction curves of FIGS. 4A-4D
respectively show the fluorescence from the nucleic acid bases A, T, G and
C. In comparison with the fluorescence lifetime of T and that of C, which
cannot be discriminated by phosphorescence, it is apparent that there is a
difference in the extinction curve therebetween. Accordingly T and C can
be discriminated from each other by fluorescence lifetime.
This method can be used to discriminate A from G by phosphorescence
lifetime. However, but taking into account ultra-high speed sequencing,
(at a speed at which one base can be identified per 1 second at worst),
the respective phosphorescence lifetimes of A and G are too long to be
used as a parameter for the discrimination of the nucleic acid bases.
The method discrimination by phosphorescence lifetime cannot be used for T
or C, because T and C emit no phosphorescence. Accordingly T and C have to
be discriminated from each other using respective fluorescence lifetimes.
As a result, a problem exists in the current art that the nucleic acid
bases contained in DNA cannot be discriminated from one another
efficiently at ultra-high speed.
FIG. 5 shows relationships between fluorescence lifetimes of long lifetime
components and ratios of the components. But as shown in FIG. 5, there are
cases in which the discrimination is difficult, and made possible only by
comparison of fluorescence lifetimes. Based on the long lifetime
components, the ratio of the fluorescence lifetime 365 ps of C is 77.6%,
which can be apparently discriminated from the other three nucleic acids
A, T, G. But it is difficult to discriminate A, T, G by long lifetime
components. Furthermore, even if G can be discriminated, it will be
difficult to discriminate A from T.
SUMMARY OF THE INVENTION
In view of these problems in the art, an object of this invention is to
provide a method of discriminating a kind of nucleic acid base at
ultra-high speed without any pre-treatment addition of fluorescence dye to
the nucleic acid bases.
A discriminating method according to this invention comprises the steps of:
adding a sample including any nucleic acid to a polar vitreous solvent;
cooling the same at very low temperature, adding a fluorescence
intensifying agent to the vitreous solution and irradiating an excitation
light thereto, measuring lifetimes of fluorescence from the solution; and
discriminating each kind of the nucleic acid bases included in the sample,
based on measured lifetimes of fluorescence from the vitreous solvent.
The vitreous (glassy) solvent is a polar solvent wherein the nucleic acid
bases are soluble therein, which are polar molecules, such as alcohol, a
mixed liquid of alcohol and water, a mixed liquid of alcohol and ether or
ketone, etc. It is preferable that the fluorescence intensifying agent is
a strong acid having no absorption spectrum in a wavelength range of the
excitation light.
According to this invention, a fluorescence intensifying agent of (n,
.pi.*) quencher is added to a sample solution at a low temperature,
whereby differences in fluorescence lifetime can therefore be made readily
distinguished.
A strong acid having no absorption spectrum in a wavelength range of the
excitation light is used as the fluorescence intensifying agent. As a
result protons are added to non-bonding electron pairs of the nucleic acid
bases, whereby (n, .pi.*) states can be extinguished.
Changes of the electron state of the sample solution due to the addition of
(n, .pi.*) quencher, for example, 0.1N hydrochloric acid are explained as
follows. In the case where A and G are in a mixed solvent (77K) of a polar
vitreous solution, for example, neutral or alkaline water and alcohol, the
energy level of the single state (S), in which the electron spins are
anti-parallel, and that of the triplet state (T), in which the electron
spins are parallel, are on a level higher than their respective (n, .pi.*)
state (FIG. 6A). When light is irradiated to the sample solution,
electrons in the ground state are excited to the lowest single state
(.pi., .pi.*). In accordance with the El-Sayed rule, inter system crossing
from the S.sub.1 (.pi., .pi.*) to the higher excited triplet state T.sub.2
(n, .pi.*) tends to take place. The electrons in T.sub.2 (n, .pi.*) state
transit to the lowest excited triplet state T.sub.1 (n, .pi.*) due to the
internal conversion, and when they transit further to the ground state,
they emit phosphorescence. But the addition of a (n, .pi.*) quencher, for
example, hydrochloric acid of 0.1N, to the sample solution, H.sup.+ s
dissociated in the solution are added to non-bonding electron pairs in the
n orbitals of the nucleic acid bases, and then the S2(n, .pi.*) state and
the T2(n, .pi.*) state are extinguished (FIG. 6B). Accordingly inter
system crossing is blocked, and the emission of phosphorescence is
diminished.
In the case of nucleic acid base A, it is considered that, because of an
equilibrium constant of the acid-base reaction in which non-bonding
electron pairs of a chromophore combine with H.sup.+ s, the electron state
of the sample solution with a (n, .pi.*) quencher added, for example,
hydrochloric acid of 0.1N, has the mixed states as shown FIGS. 6A and 6B.
Accordingly the emission of phosphorescence cannot be completely
suppressed, but a small increase of fluorescence ratio to phosphorescence
is obtained.
In the cases of nucleic acid bases T and C, as shown in FIG. 6C, T.sub.2
(n, .pi.*) state is on a higher level than S.sub.1 (.pi., .pi.*) state.
Accordingly no effective inter-system crossing through T.sub.2 (n, .pi.*)
state takes place, and the emission of phosphorescence is small.
Consequently, even with the addition of a (n, .pi.*) quencher, for
example, hydrochloric acid of 0.1N to the sample solution, no
phosphorescence is emitted because T.sub.2 (n, .pi.*) state does not
originally contribute to the inter-system crossing from the S.sub.1 (.pi.,
.pi.*) state, and the quenching is not effective.
Next, the fluorescence and the phosphorescence yields of the four kinds of
nucleic acid bases, and temperature dependence of fluorescence lifetimes
thereof, are briefly explained as follows. Generally, a fluorescence yield
.PHI..sub.f is given by the following Formula 1.
##EQU1##
Generally a fluorescence lifetime .tau..sub.f is given by the following
Formula 2.
##EQU2##
In the above-described formulas, kf represents a speed constant of the
fluorescence; KIC, a rate constant of an internal conversion independent
of a temperature; KISC, a rate constant for cases where T.sub.2 (n, .pi.*)
energy level contributes to an inter-system crossing; KISC', a rate
constant for cases where T.sub.2 (n, .pi.*) energy level does not
contribute to an inter-system crossing; and Kexp(-.DELTA.E/RT), a rate
constant for an internal conversion dependent on a temperature. It is
experimentally known that the temperature dependent rate is of an
exp(-.DELTA.E/RT) form, and .DELTA.E represents activation energy, and R
is a gas constant. FIG. 7 shows results given by replacing the respective
speed constants and the activation energy assuming reasonable values, and
shows changes of the temperature corresponding to values of
Kexp(-.DELTA./RT). As shown there, since the fluorescence yield .PHI.f
significantly decreases at temperatures higher than 150 K, it is
preferable to measure the fluorescence lifetime at a temperature below
150K. Below 100K, Kexp(-.DELTA.E/RT) is sufficiently negligible in
comparison with the other rate constants. An arbitrary temperature below
100K may be used for increasing the fluorescence yield .PHI..sub.f.
The present invention will become more fully understood from the detailed
description given hereinbelow and the accompanying drawings which are
given by way of illustration only, and thus are not to be considered as
limiting the present invention.
The further scope of applicability of the present invention will become
apparent from the detailed description given hereinafter. However, it
should be understood that the detailed description and specific examples,
while indicating preferred embodiments of the invention, are given by way
of illustration only, since various changes and modifications within the
spirit and scope of the invention will become apparent to those skilled in
the art from this detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1A-1D show molecular structures of deoxynucleotides in DNA,
respectively;
FIGS. 2A-2D show molecular structures of DNA and nucleic acid bases,
respectively;
FIGS. 3A-3D are fluorescence and phosphorescence spectra without the
addition of a (n, .pi.*) quencher;
FIGS. 4A-4D are fluorescence decay curves without the addition of a
(n,.pi.*) quencher;
FIG. 5 is a table of fluorescence lifetime of components and ratios of the
components without the addition of a (n,.pi.*) quencher;
FIGS. 6A-6C are schematic energy diagrams of nucleic acid bases to
illustrate fluorescence and phosphorescence properties;
FIG. 7 shows the relationship between temperatures and rate constants of
the temperature-dependent internal conversion in the single state;
FIG. 8A shows fluorescence decay curves obtained by the method for
discriminating nucleic acid bases according to this invention;
FIG. 8B shows fluorescence decay curves of the samples to which quencher is
not added;
FIG. 9A shows fluorescence lifetime components, and ratios of the
components obtained by the method for discriminating nucleic acid bases
according to this invention;
FIG. 9B shows average fluorescence lifetimes corresponding to A, T, G and C
obtained from the experimental results shown in FIG. 8A and FIG. 8B; and
FIGS. 10A and 10B are absorption spectra with and without the addition of a
(n,.pi.*) quencher.
DETAILED DESCRIPTION OF THE INVENTION
The nucleic acid bases discriminating method according to one example of
this invention will be explained below.
First, four samples respectively including DNA bases A, T, G and C were
prepared. Concretely, the four kinds of DNA bases were used as supplied
(Yamasa Syoyu): disodium salt of: deoxy adenosine 5'-monophosphate (dAMP),
deoxy guanosine 5'-monophosphate (dGMP), deoxy thymidine 5'-monophosphate
(dTMP), and deoxy cytidine 5'-monophosphate (dCMP). All the bases were
dissolved in 0.1N HCl (ca. 4.times.10.sup.-5 M) mixed with methanol (Dojin
Luminasol). The ratio of mixing was 1:1 by volume. The concentration of
each base was 2.5.times.10.sup.-5 mol/liter in each of the samples. Next
the temperature of each of the solvents was decreased to 77K. Next, UV
beams irradiated the cooled solvent and the fluorescence intensity from
the solvent due to the U.V. radiation was detected in each of the four
samples by using a picosecond time-resolved fluorometer, for example, as
shown in the reference titled as "Single-Photon Sensitive Synchroscan
Streak Camera for Room Temperature Picosecond Emission Dynamic of Adenine
and Polyadenylic Acid" in IEEE Journal of Quantum Electronics. Vol. QE-20,
No. 12 December 1984. Concretely, the picosecond time-resolved
fluorometer was composed of an exiting light source and a detector. The
light source was a mode-locked and cavity-dumped fluorescein 548 dye laser
(Spectra-Physics 375B and 344) synchronously pumped by a mode-locked cw
Ar.sup.+ laser (Spectra-Physics 2030). The detector was a synchroscan
streak camera (Hamamatsu C1587 equipped with a M2171 synchroscan unit for
4 MHz operation) coupled with a polychromator (Jobin-Y von HR320, 150
grooves/mm). A second harmonic generation was carried out by means of a 8
mm thick .beta.-Ba B.sub.2 O.sub.4 (Type 1,51.degree.) crystal. Picosecond
pulses at the repetition rate of 4 MHz, having an average power of ca. 1.5
mW at 270 nm, were used to excite four kind of DNA bases. The fluorescence
photons from the DNA bases were detected at a right angle to a vertically
polarized exciting laser beam without a polarizer. Sample cuvettes (4 mm
in diameter) and a Dewar vessel for liquid nitrogen were made of
fluorescence-free quartz.
FIG. 8A shows the fluorescence decay curves with the irradiation of UV to
the four samples obtained by the above method, that is, in the samples,
where 0.1N hydrochloric acid is added. On the contrary, FIG. 8B shows the
fluorescence decay curves of the samples including each of DNA bases but
to which hydrochloric acid was not added as a (n,.pi.*) quencher. In FIGS.
8A and 8B, fluorescence intensity is taken on the vertical axis, and time
is taken on the horizontal axis. 1 ch of the horizontal axis is equal to
77 psec. A peak appearing at about 100 ch indicates excitating light
pulse, and the decay curves came from fluorescence from the nucleic acid
bases. As seen from these views, the respective nucleic acid bases have
different decay curves, and there are differences in the fluorescence
lifetimes. As shown in comparison of FIG. 8A with FIG. 8B, by the addition
of 0.1N hydrochloric acid, the discrimination of four kinds of DNA bases
becomes easier using fluorescence lifetimes. As a result, of the above
method high speed and accurate discrimination can be realized.
FIG. 9A shows the relationships between these fluorescence lifetimes and
ratios of the lifetime components, and FIG. 9B shows average fluorescence
lifetimes of four samples, respectively, including each of four kinds of
nucleic acid bases therein. As seen in FIG. 9A and 9B, it is possible to
discriminate the four kinds of nucleic acid bases from one another without
pretreatment, based on the ratios of the lifetime components or average
fluorescence lifetimes. In particular, FIG. 9B shows the comparison
between the average lifetimes of fluorescence in the samples to which 0.1N
hydrochloric acid is added to samples to which quencher is not added. As
shown in FIG. 9B, in the samples to which 0.1N hydrochloric acid is added,
the lifetimes of fluorescence in the samples can be clearly discriminated.
As described above, differences among the fluorescence lifetimes of nucleic
acid bases A, T, G and C are made clear by the addition of a (n,.pi.*)
quencher. The fluorescence lifetime of G especially differs after the
addition of the (n,.pi.*) quencher. This could be due to differences in
the reactivity of the nucleic acid bases toward H.sup.+ s of the (n,.pi.*)
quencher. The effect of the (n,.pi.*) quencher is enhancement of the
fluorescence vitreous to phosphorescence with a result that differences
are produced in the fluorescence lifetimes among the bases. These results
are accompanied by absorption spectra of the four kinds of bases (FIG.
10).
The discriminating method based on fluorescence lifetimes of the four kinds
of nucleic acid bases which is enabled by the addition of a (n,.pi.*)
quencher has been described above.
In this embodiment, the (n,.pi.*) quencher was provided by hydrochloric
acid. The effect of the addition of the quencher possibly derives from the
fact that H.sup.+ s are combined (protonized) with non-bonding electron
pairs in carbonyl groups and in nitrogen contained in the aromatic rings,
which are contained in all of A, T, G and C. Accordingly the quencher is
not limited to hydrochloric acid, and acids (e.g., hydrochloric acid,
sulfuric acid and nitric acid) which can protonize non-bonding electron
pairs could be used. But the acids (e.g., trichloroacetic acid) having
absorption spectra in a wavelength range (250.about.290 nm) of the
excitation light are not suitable. It is necessary that the solvent can
sufficiently dissolve samples, and is glassy at low temperatures. In
solutions without such properties, when frozen at low temperatures, the
solvent itself forms fine crystals in white powder which does not easily
transmit light. In the case that samples are polar molecules, polar
solvents which well dissolve the sample are preferred. Such as mixed
solutions of water and alcohols (e.g., methanol, ethanol, ethylene glycol,
isopropanol) of arbitrary mixing ratios. The alcohol alone, and solutions
of these alcohols and ether or ketone of arbitrary mixing ratios are
widely used. That is, it is necessary that components mix well with each
other to form random liquid structures.
As described above, the addition of a fluorescence intensifier, such as
hydrochloric acid, to the solvent makes differences in fluorescence
lifetime among the four kinds of nucleic acid bases A, T, G, and C quite
clear. By comparing fluorescence lifetimes of A, T, G and C observed based
on their differences, A, T, G and C could be discriminated from one
another at ultra-high speed. Furthermore, by suitable selection of
wavelengths of the excitation light (see FIG. 10A and 10B, where
separation of the peak wavelengths is noticeable when an (n,.pi.*)
quencher is added), as long as these bases have sufficient numbers of
molecules, these bases can be accurately discriminated from one another by
the measurements of the fluorescence lifetimes and those of the four kinds
of nucleic acid bases.
Furthermore, the fluorescence can be intensified by the extinguishing
(n,.pi.*) state, which contributes to the high speed discrimination of the
nucleic acid bases.
Although the above embodiments described four kinds of samples including a
large number of molecules, the present invention can be applied to the
discrimination of single-molecule samples.
From the invention thus described, it will be obvious that the invention
could be varied in many ways. Such variations are not to be regarded as a
departure from the spirit and scope of the invention, and all such
modifications as would be obvious to one skilled in the art are intended
to be included within the scope of the following claims.
* * * * *
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