NZ760030A - Sensor And Sensing System - Google Patents
Sensor And Sensing SystemInfo
- Publication number
- NZ760030A NZ760030A NZ760030A NZ76003019A NZ760030A NZ 760030 A NZ760030 A NZ 760030A NZ 760030 A NZ760030 A NZ 760030A NZ 76003019 A NZ76003019 A NZ 76003019A NZ 760030 A NZ760030 A NZ 760030A
- Authority
- NZ
- New Zealand
- Prior art keywords
- gap
- nucleotide
- nucleotides
- electrodes
- strand
- Prior art date
Links
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Abstract
sensor includes two electrodes and a modulatable electrically conductive channel attached to the two electrodes. The modulatable electrically conductive channel includes a modified, partially double stranded nucleic acid polymer electrically connected to the two electrodes and bridging the space between the two electrodes. The modified, partially double stranded nucleic acid polymer includes two polynucleotide chains partially bonded together, a gap in a first of the polynucleotide chains wherein nucleotide bases are missing, and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains. between the two electrodes. The modified, partially double stranded nucleic acid polymer includes two polynucleotide chains partially bonded together, a gap in a first of the polynucleotide chains wherein nucleotide bases are missing, and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains.
Description
SENSOR AND SENSING SYSTEM
CROSS-REFERENCE TO RELATED APPLICATIONS
This application claims the benefit of U.S. Provisional Application Serial
Number 62/692,468, filed June 29, 2018, and Netherland Application Serial Number
N2021376, filed July 23, 2018; the content of each of which is incorporated by reference
herein in its entirety.
REFERENCE TO SEQUENCE LISTING
The Sequence Listing submitted herewith via EFS-Web is hereby
incorporated by reference in its entirety. The name of the file is ILI149BPCT_IP
PCT_sequence_listing_ST25.txt, the size of the file is 366 bytes, and the date of
creation of the file is June 7, 2019.
BACKGROUND
Various protocols in biological or chemical research involve performing a
large number of controlled reactions on local support surfaces or within predefined
reaction chambers. The designated reactions may then be observed or detected and
subsequent analysis may help identify or reveal properties of chemicals involved in the
reaction. For example, in some multiplex assays, an unknown analyte having an
identifiable label (e.g., fluorescent label) may be exposed to thousands of known probes
under controlled conditions. Each known probe may be deposited into a corresponding
well of a microplate. Observing any chemical reactions that occur between the known
probes and the unknown analyte within the wells may help identify or reveal properties
of the analyte. Other examples of such protocols include known DNA sequencing
processes, such as sequencing-by-synthesis (SBS) or cyclic-array sequencing. With
polynucleotide sequencing techniques, the analysis may help identify or reveal
properties of the polynucleotide involved in the reactions.
INTRODUCTION
A first aspect disclosed herein is a sensor. In an example, the sensor
comprises two electrodes having a space therebetween; and a modulatable electrically
conductive channel attached to the two electrodes, the modulatable electrically
conductive channel including a modified, partially double stranded nucleic acid polymer
electrically connected to the two electrodes and bridging the space between the two
electrodes, the modified, partially double stranded nucleic acid polymer including: two
polynucleotide chains partially bonded together; a gap in a first of the polynucleotide
chains wherein nucleotides are missing; and a plurality of nucleotide bases of a second
of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains.
In an example of the sensor, the gap has a length ranging from about 10 nm
to about 50 nm.
An example of the sensor further comprises a polymerase attached to the
modified, partially double stranded nucleic acid polymer.
In an example of the sensor, i) linkers respectively attach each end of the first
of the polynucleotide chains to a respective one of the two electrodes; or ii) linkers
respectively attach each end of the second of the polynucleotide chains to a respective
one of the two electrodes; or iii) both i and ii.
In an example of the sensor, at least one of the plurality of nucleotide bases
exposed at the gap is a guanine base.
In an example of the sensor, each of the plurality of nucleotide bases
exposed at the gap is a guanine base.
An example of the sensor further comprises a detector to detect a response
from the modified, partially double stranded nucleic acid polymer when a switch strand,
including a strand of nucleotides including bases complementary to at least some of the
plurality of nucleotide bases exposed at the gap, associates with the at least some of
the plurality of nucleotide bases at the gap.
An example of the sensor further comprises a substrate supporting the two
electrodes; and a polymerase attached to the substrate.
An example of the sensor further comprises a fluidic system to introduce a
reagent to the modified, partially double stranded nucleic acid polymer. In an example,
the reagent includes labeled nucleotides, at least one of the labeled nucleotides
including: a nucleotide; a linking molecule attached to a phosphate group of the
nucleotide; and a switch strand attached to the linking molecule, the switch strand
including a strand of nucleotides including bases complementary to at least some of the
plurality of nucleotide bases exposed at the gap.
An example of the sensor further comprises a plurality of other modulatable
electrically conductive channels attached to the two electrodes, each of the other
modulatable electrically conductive channels including a respective modified, partially
double stranded nucleic acid polymer electrically connected to the two electrodes and
bridging the space between the two electrodes.
In an example of the sensor, the modulatable electrically conductive channel
exhibits a first conductance when the plurality of nucleotide bases are exposed at the
gap; and a second conductance that is different than the first conductance when at least
some of the plurality of nucleotide bases at the gap are associated with complementary
nucleotide bases.
It is to be understood that any features of the sensor disclosed herein may be
combined together in any desirable manner and/or configuration, and/or with any other
example disclosed herein.
A second aspect disclosed herein is a labeled nucleotide, comprises a
nucleotide; a linking molecule attached to a phosphate group of the nucleotide; and a
switch strand attached to the linking molecule, the switch strand including a strand of
nucleotides including bases complementary to at least some of the plurality of
nucleotide bases exposed at the gap of the sensor of the first aspect.
A third aspect disclosed herein is a kit, comprising: an electronic component,
including: a support; and two electrodes operatively disposed on the support and
separated by a space; and a polymeric solution, including: a liquid carrier; and a
modified, partially double stranded nucleic acid polymer in the liquid carrier, the
modified, partially double stranded nucleic acid polymer including: two polynucleotide
chains partially bonded together and having opposed ends; a linker attached to each of
the opposed ends, each linker to attach to a respective one of the two electrodes; a gap
in a first of the polynucleotide chains wherein nucleotides are missing; and a plurality of
nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first
of the polynucleotide chains; the modified, partially double stranded nucleic acid
polymer to form a modulatable electrically conductive channel in the space between the
two electrodes when each linker attaches to the respective one of the two electrodes.
In an example, the kit further comprising a reagent solution including labeled
nucleotides, at least one of the labeled nucleotides including: a nucleotide; a linking
molecule attached to a phosphate group of the nucleotide; and a switch strand attached
to the linking molecule, the switch strand including a strand of nucleotides including
bases complementary to at least some of the plurality of nucleotide bases exposed at
the gap. In an example of the kit, the bases in the switch strand are completely
complementary to the plurality of nucleotide bases exposed at the gap. In another
example of the kit, the switch strand further includes at least one nucleotide having a
mismatched base that is non-complementary to a corresponding one of the plurality of
nucleotide bases exposed at the gap. In still another example of the kit, the strand of
nucleotides in the switch strand has at least one nucleotide fewer than the plurality of
nucleotide bases exposed at the gap. In yet a further example of the kit, the strand of
nucleotides in the switch strand has a higher number of nucleotides than the plurality of
nucleotide bases exposed at the gap, and wherein a portion of the switch strand forms a
stem loop when associated at the gap. In an example of the kit, the strand of
nucleotides in the switch strand has a higher number of nucleotides than the plurality of
nucleotide bases exposed at the gap; a portion of the switch strand forms a stem loop
when associated at the gap; and another portion of the switch strand is completely
complementary to the plurality of nucleotide bases exposed at the gap or includes at
least one nucleotide having a mismatched base that is non-complementary to a
corresponding one of the plurality of nucleotide bases exposed at the gap.
It is to be understood that any features of the kit may be combined together in
any desirable manner. Moreover, it is to be understood that any combination of
features of the kit and/or of the sensor and/or of the labeled nucleotide may be used
together, and/or combined with any of the examples disclosed herein.
In a fourth aspect, a sensing system comprises a flow cell; and an electronic
sensor integrated into the flow cell, the electronic sensor including: two electrodes
having a space therebetween; a modulatable electrically conductive channel attached to
the two electrodes, the modulatable electrically conductive channel including a modified,
partially double stranded nucleic acid polymer electrically connected to the two
electrodes and bridging the space between the two electrodes, the modified, partially
double stranded nucleic acid polymer including: two polynucleotide chains partially
bonded together; a gap in a first of the polynucleotide chains wherein nucleotides are
missing; and a plurality of nucleotide bases of a second of the polynucleotide chains
exposed at the gap in the first of the polynucleotide chains.
In an example, the sensing system further comprises a reagent delivery
system to selectively introduce a reagent to an input of the flow cell. In an example, the
reagent is in a sample container, the reagent including labeled nucleotides, at least one
of the labeled nucleotides including: a nucleotide; a linking molecule attached to a
phosphate group of the nucleotide; and a switch strand attached to the linking molecule,
the switch strand including a strand of nucleotides including bases complementary to at
least some of the plurality of nucleotide bases exposed at the gap.
An example of the sensing system further comprises a detector to detect a
response from the electronic sensor.
An example of the sensing system further comprises a polymerase anchored
to the modified, partially double stranded nucleic acid polymer or a support of the
electronic sensor; and a template polynucleotide chain to be introduced to the electronic
sensor.
It is to be understood that any features of the sensing system may be
combined together in any desirable manner. Moreover, it is to be understood that any
combination of features of the sensing system and/or of the sensor, and/or of the kit
and/or of the labeled nucleotide may be used together, and/or combined with any of the
examples disclosed herein.
A fifth aspect disclosed herein is a method. In an example, the method
comprises introducing a template polynucleotide chain to an electronic sensor having a
polymerase tethered to i) a modulatable electrically conductive channel that bridges a
space between, and is electrically connected to two electrodes or ii) a substrate
supporting the two electrodes, the modulatable electrically conductive channel including
a modified, partially double stranded nucleic acid polymer, which includes: two
polynucleotide chains partially bonded together; a gap in a first of the polynucleotide
chains wherein nucleotides are missing; and a plurality of nucleotide bases of a second
of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains;
introducing reagents including labeled nucleotides to the electronic sensor, whereby a
nucleotide of one of the labeled nucleotides associates with the polymerase and a
nucleotide-specific switch strand of the one of the labeled nucleotides associates with at
least some of the plurality of nucleotide bases exposed at the gap; and in response to
the association at the gap, detecting a response of the electronic sensor.
An example of the method further comprises associating the response of the
electronic sensor with the associated nucleotide-specific switch strand; and based on
the associated nucleotide-specific switch strand, identifying the nucleotide of the one of
the labeled nucleotides.
An example of the method further comprises heating to disassociate the
nucleotide-specific switch strand from the gap.
It is to be understood that any features of the method may be combined
together in any desirable manner. Moreover, it is to be understood that any
combination of features of the method and/or of the sensing system and/or of the
sensor and/or any of the kits and/or of the labeled nucleotide may be used together,
and/or combined with any of the examples disclosed herein.
BRIEF DESCRIPTION OF THE DRAWINGS
Features of examples of the present disclosure will become apparent by
reference to the following detailed description and drawings, in which like reference
numerals correspond to similar, though perhaps not identical, components. For the
sake of brevity, reference numerals or features having a previously described function
may or may not be described in connection with other drawings in which they appear.
Fig. 1A is a schematic diagram of an example of a sensor disclosed herein;
Fig. 1B is a schematic diagram of an example of a sensor and an example of
a fluidic system to introduce a reagent to a modified, partially double stranded nucleic
acid polymer of the sensor;
Fig. 2 is a schematic diagram of an example of a labeled nucleotide disclosed
herein;
Figs. 3A through 3D are cutaway schematic diagrams of different example
labeled nucleotides, including different switch strands, associated with nucleotide bases
exposed at a gap of a modified, partially double stranded nucleic acid polymer;
Fig. 4 is a schematic, perspective diagram of an example of a sensing system
including a flow cell and an example of the sensor disclosed herein;
Fig. 5 is a schematic diagram of an example of a sensing system; and
Fig. 6 is a flow diagram of an example of a method disclosed herein.
DETAILED DESCRIPTION
An electronic/electrical sensor is disclosed herein which may be used for
single molecule detection in nucleic acid sequencing procedures. The sensor includes
a modulatable electrically conductive channel electrically attached to two electrodes.
The modulatable electrically conductive channel includes a modified, partially double
stranded nucleic acid polymer (referred to herein as the modified “dsNA”), and thus may
be referred to as a conductive molecular nanowire. One polynucleotide chain or strand
of the modified dsNA has a gap where nucleotide bases are exposed. The other of the
polynucleotide chains or strands extends from one of the electrodes to the other of the
electrodes, and thus the modulatable electrically conductive channel provides a
conduction path between the two electrodes even when the nucleotide bases at the gap
are exposed (and single molecule detection is not taking place). The nucleotide bases
at the gap are able to associate with a switch strand having at least some nucleotide
bases complementary to the nucleotide bases at the gap. When the switch strand
associates at the gap, the conduction path increases and the conductance of the
electrically conductive channel is modulated. As such, the modulatable electrically
conductive channel exhibits a first conductance when the plurality of nucleotide bases
are exposed at the gap; and a second conductance that is different than the first
conductance when at least some of the plurality of nucleotide bases at the gap are
associated with complementary nucleotide bases. In an example, when the nucleotide
bases at the gap are exposed, the conductivity of the modulatable electrically
conductive channel is relatively low. In contrast, when the switch strand associates at
the gap, the conductivity of the modulatable electrically conductive channel changes
(e.g., increases or decreases), in some instances, by orders of magnitude.
The switch strand may be part of a labeled nucleotide, which includes a
specific nucleotide linked to the switch strand. As the specific nucleotide is being
incorporated into a nascent strand during a nucleic acid sequencing procedure, the
switch associates at the gap, which results in a conductivity change of the modulatable
electrically conductive channel. Since the nucleotide and the switch strand are specific
to one another, the conductivity change associated with the switch is also associated
with the nucleotide. As such, the change in conductivity may be used to identify the
nucleotide base being incorporated into the nascent strand.
Referring now to Fig. 1A, an example of the sensor 10 is depicted. The
example sensor 10 is an electrical/electronic sensor. The sensor 10 includes two
electrodes 12, 14 having a space therebetween, and a modulatable electrically
conductive channel 16 attached to the two electrodes 12, 14. The modulatable
electrically conductive channel includes a modified, partially double stranded nucleic
acid polymer (i.e., modified dsNA) 16’ electrically connected to the two electrodes 12,
14 and bridging the space between the two electrodes 12, 14, the modified dsNA 16’
including two polynucleotide chains 18, 20 partially bonded together; a gap 22 in a first
of the polynucleotide chains 18 wherein nucleotides are missing; and a plurality of
nucleotide bases 24 of a second of the polynucleotide chains 20 exposed at the gap 22
in the first of the polynucleotide chains 18.
The electrodes 12, 14 are in electrical communication with the modified dsNA
16’/modulatable electrically conductive channel 16, and thus a constant conduction path
exists between the electrodes 12, 14 when the sensor 10 is in operation. As mentioned,
this conduction path is modulatable by the association of a switch strand at the gap 22.
Any suitable electrode material may be used that can chemically and
electrically attach to the modified dsNA 16’. Examples of suitable electrode materials
include gold, platinum, carbon, indium tin oxide, etc.
The modified dsNA 16’ is a nucleic acid polymer which includes two
polynucleotide chains 18, 20 partially bonded together. By “partially bonded together”, it
is meant that some of the nucleotide bases of the two chains 18, 20 are hydrogen
bonded to one another to form a double helix, but that one of the chains 18 has a gap
22 without any nucleotides. At the gap 22 in the one chain 18, the nucleotide bases of
the other of the chains 20 are exposed. By “exposed”, it is meant that the bases of
these nucleotides are not bonded to another nucleotide, and thus are available to be
bound, hybridized, or otherwise associated with complementary nucleotides.
The nucleotides of the two polynucleotide chains 18, 20 may be natural
nucleotides. Natural nucleotides include a nitrogen containing heterocyclic base, a
sugar, and one or more phosphate groups. Examples of natural nucleotides of the two
polynucleotide chains 18, 20 include ribonucleotides or deoxyribonucleotides. In
ribonucleotides, the sugar is a ribose, and in deoxyribonucleotides, the sugar is a
deoxyribose, i.e. a sugar lacking a hydroxyl group that is present at the 2' position in
ribose. In an example, the nucleotide is in the polyphosphate form because it includes
several phosphate groups (e.g., tri-phosphate (i.e., gamma phosphate), tetra-
phosphate, penta-phosphate, hexa-phosphate (as shown in Fig. 5), etc.). The
heterocyclic base (i.e., nucleobase) can be a purine base or a pyrimidine base or any
other nucleobase analog. Purine bases include adenine (A) and guanine (G), and
modified derivatives or analogs thereof. Pyrimidine bases include cytosine (C), thymine
(T), and uracil (U), and modified derivatives or analogs thereof. The C-1 atom of
deoxyribose is bonded to N-1 of a pyrimidine or N-9 of a purine. The polynucleotide
chains 18, 20 may also include any nucleic acid analogs. A nucleic acid analog may
have any of the phosphate backbone, the sugar, or the nucleobase altered. Examples
of nucleic acid analogs include, for example, universal bases or phosphate-sugar
backbone analogs, such as peptide nucleic acid (PNA).
As mentioned herein, the first polynucleotide chain 18 has a gap 22 where
nucleotides are not present. The gap 22 may be located anywhere along the chain 18,
for example, at or near the center, at either end of the chain 18, between the center and
one end of the chain 18, etc. As such, in some examples, the first polynucleotide chain
18 includes two shorter chains separated by the gap 22. In other examples (e.g., when
the gap 22 is at either end of the chain 18), the first polynucleotide chain 18 is a single
continuous chain. In still other examples, the first polynucleotide chain 18 may have
multiple gaps 18 along the polymer backbone. The gap(s) 22 may have any length that
is shorter than the total length of the dsNA 16’. In an example, the length of each gap
22 ranges from about 5 nm to about 60 nm. In another example, the length of each gap
22 ranges from about 10 nm to about 50 nm. In still another example, the length of
each gap 22 ranges from about 20 nm to about 40 nm. While the length of the gap 22
is set forth as a metric unit, it is to be understood that the gap length may also be
defined in terms of the number of nucleotides that could fit into the gap 22, or the
number of nucleotide bases of the second polymeric chain 20 that are exposed at the
gap 22. The gap(s) 22 in the first polynucleotide chain 18 reduces the conductivity of
the modified dsNA 16’.
At the gap 22 in the first polynucleotide chain 18, a plurality of nucleotides of
the second polymeric chain 20 are exposed. In particular, the bases 24 of these
nucleotides are exposed. The exposed bases 24 may all be the same bases or may be
a combination of different bases. In an example, at least one of the exposed bases 24
is guanine (G). In this example, the other exposed bases 24 may be any one of or any
combination of adenine (A), cytosine (C), thymine (T), and/or uracil (U). In another
example, each of the exposed bases 24 is guanine (G). It may be desirable to include
several guanine (G) bases in a row exposed at the gap 22, as the guanine (G) bases
conduct electricity better than the other bases.
The two, partially bonded polynucleotide chains have opposed ends, and a
linker may be attached to each of the opposed ends. In the examples disclosed herein,
i) linkers respectively attach each end of the first of the polynucleotide chains 18 to a
respective one of the two electrodes 12, 14; or ii) linkers respectively attach each end of
the second of the polynucleotide chains to a respective one of the two electrodes; or iii)
both i and ii. While Fig. 1 illustrates the second polynucleotide chain 20 bonded to the
electrodes 12, 14 through the linkers 26, it is to be understood that the first
polynucleotide chain 18 or both chains 18, 20 may be bonded to the electrodes 12, 14
through respective linkers 26. As such, the respective 5’ and 3’ ends of the first and/or
the second polynucleotide chain 18, 20 may have a linker 26 attached thereto. The
linkers 26 electrically connected the modified dsNA 16’ to the electrodes 12, 14. The
linkers 26 may also be capable of chemically bonding to the respective electrodes 12,
14, thus bridging the modified dsNA 16’ between the electrodes 12, 14. Therefore, the
linkers 26 may depend upon the electrode material. As examples, thiolate or amine
linkers may attach to gold electrodes, thiol linkers may attach to platinum electrodes,
and silane linkers (e.g., azido silane) may attach to ITO electrodes. The attachment of
the respective linker 26 to one of the electrodes 12, 14 may be through covalent
bonding, coordination bonding, or another chemical or physical bond, depending upon
the linker and the electrode material. The linkers 26 are also electrically conductive so
that the conduction path between the electrodes 12, 14 is established when the
modified dsNA 16’ is attached to each of the electrodes 12, 14.
Any example of the sensor 10 disclosed herein may include a plurality of
other modulatable electrically conductive channels 16 attached to the two electrodes 12,
14, each of the other modulatable electrically conductive channels 16 including a
respective modified, partially double stranded nucleic acid polymer 16’ electrically
connected to the two electrodes 12, 14, and bridging the space between the two
electrodes 12, 14. In other words, the sensor 10 may include two or more partially
double stranded nucleic acid polymers 16’, where each modified dsNA 16’ is electrically
connected to the two electrodes 12, 14. Multiple channels 16 are relative easy to
fabricate (by allowing multiple modified dsNA 16’ strands to attach), and provide several
gaps 22 with which the switch strand(s) can associate. With multiple channels 16, the
base signal (e.g., when no switch strand(s) are associated with the gap(s) 33 is higher,
and when respective switch strands associate with the multiple modulatable electrically
conductive channels 16, the detected signal may be enhanced.
While not shown in Fig. 1A, the sensor 10 may also include a substrate or
support upon which the electrodes 12, 14 are positioned. An example of the
support/substrate 13 is shown in Fig. 1C. The support/substrate 13 may be any solid
surface upon which the electrodes 12, 14 can sit. Any non-conductive or semi-
conductive solid surface may be used. The solid surface may also be non-permeable
of, and inert to liquids, reagents, etc. used in a single molecule sequencing operation.
Some examples of suitable supports/substrates 13 include epoxy siloxane, glass and
modified or functionalized glass, plastics (including acrylics, polystyrene and
copolymers of styrene and other materials, polypropylene, polyethylene, polybutylene,
polyurethanes, polytetrafluoroethylene (such as TEFLON® from Chemours), cyclic
olefins/cyclo-olefin polymers (COP) (such as ZEONOR® from Zeon), polyimides, etc.),
nylon, ceramics/ceramic oxides, silica, fused silica, or silica-based materials, aluminum
silicate, silicon and modified silicon (e.g., boron doped p+ silicon), silicon nitride (Si3N4),
silicon oxide (SiO ), tantalum pentoxide (TaO ) or other tantalum oxide(s) (TaO ),
2 5 x
hafnium oxide (HaO ), inorganic glasses, or the like. The support or substrate 13 may
also be glass or silicon, with a coating layer of silicon dioxide or tantalum oxide or
another ceramic oxide at the surface.
Also while not shown in Fig. 1A, the sensor 10 may also include a detector
that can detect an electrical response of the sensor 10. Examples of the detector 15
are shown in Figs. 1B, 4, and 5. In an example, the detector 15 is an ammeter. As will
be described in more detail with reference to Fig. 5, the conductivity of the modified
dsNA 16’ (and thus the modulatable electrically conductive channel 16) may increase
when a switch strand 28 (shown in Fig. 2), including a strand of nucleotides including
bases complementary to at least some of the plurality of nucleotide bases 24 exposed
at the gap 22, associates with the at least some of the plurality of nucleotide bases 24 at
the gap 22.
As shown in Fig. 1B, the sensor 10 may further include a fluidic system 17 to
introduce a reagent to the modulatable electrically conductive channel 16. This fluidic
system 17 may be any fluidic device that can deliver the reagent to the dsNA 16’, or that
enables the reagent to be contained within proximity of the dsNA 16’. As shown in Fig.
1B, the fluidic system 17 may be a flow cell lid that can be attached to and removed
from the support/substrate 13. This example of the fluidic system 17 includes an inlet
19 through which the reagent may be introduced. The walls of this fluidic system
maintain the reagent within proximity of the dsNA 16’. As another example (not shown),
the fluidic system 17 may be a pipette (or other delivery device) that can be used to
deliver the reagent to the modulatable electrically conductive channel 16/dsNA 16’. In
this example, the support/substrate 13 may have a trench adjacent to the modulatable
electrically conductive channel 16/dsNA 16’ that can receive the reagent and enable the
reagent to contact the modulatable electrically conductive channel 16/dsNA 16’. While
some example fluidic systems have been provided, it is to be understood that the
sensor 10 may include any fluidic system 17 that can deliver a reagent to the
modulatable electrically conductive channel 16/dsNA 16’, and/or that enables the
reagent to be contained within proximity of the modulatable electrically conductive
channel 16/dsNA 16’.
The sensor 10 disclosed herein may enable single-molecule sensitivity.
Moreover, when arranged in an array (i.e., several sensors 10 positioned on a
substrate/support 13), very small inter-sensor distances may be used so that the density
(i.e., sensor/area) can be very high.
To form the sensor 10, any suitable methods may be used. In an example,
the modified dsNA 16’ may be synthesized, and then the modified dsNA 16’ may be
attached to the electrodes 12, 14 to form the modulatable electrically conductive
channel 16 in the space between the two electrodes 12, 14.
The modified dsNA 16’ may be made by synthesizing the second
polynucleotide chain 20, and then mixing the second polynucleotide chain 20 with
complementary strand(s) that will attach to the second polynucleotide chain 20 at
appropriate position(s). The mixture may then be annealed to initiate the attachment.
In an example, two complementary strands may attach to respective portions of the
second polynucleotide chain 20 so that the gap 22 is formed somewhere between the
two ends of the resulting modified dsNA 16’. In another example, one complementary
strand that is shorter than the second polynucleotide chain 20 may attach to a portion of
the second polynucleotide chain 20 so that the gap 22 is formed at one end of the
resulting modified dsNA 16’. It is to be understood that the second polynucleotide chain
and the complementary strand(s) that attach to form the first polynucleotide chain 18
may be selected to control the length of the gap 22 and the nucleotide bases 24 that are
exposed at the gap 22.
The modified dsNA 16’ may then be attached to the electrodes 12, 14. The
linkers 26 may be attached to the modified dsNA 16’ using any suitable technique, and
then the linkers 26 may be attached to the electrodes 12, 14. In an example, thiol-
modified DNA bases may be conjugated at the 3’ and 5’ ends of the chains 18, 20. In
an example, the modified dsNA 16’ may be immobilized on the electrodes 12, 14 by
exposing the electrodes 12, 14 in a solution of the modified dsNA 16’ for a suitable time,
followed by rinsing with a suitable buffer to remove non-bound modified dsNA 16’.
In a method of making of making sensor 10, the electrodes 12, 14 may also
be electrically connected to the detector 15.
In some examples, the sensor 10 may come pre-assembled.
In other examples, the sensor components may be part of a kit, and the kit
components may be used to assemble the sensor 10. An example of the kit includes an
electronic component and a polymeric solution. The electronic component includes the
support 13 and two electrodes 12, 14 operatively disposed on the support and
separated by a space. By “operatively disposed”, it is meant that the electrodes 12, 14
may be connected to electronic circuitry that enables their operation (e.g., once hooked
up to a detector 15 and power supply). The electronic circuitry may be electrically
connectable to the detector 15 and to the power supply. The polymeric solution
includes a liquid carrier and a modified dsNA 16’ in the liquid carrier, where the modified
dsNA 16’ is any of the examples described herein. As described herein, the modified
dsNA 16’ includes the two polynucleotide chains 18, 20 partially bonded together and
having opposed ends. The modified dsNA 16’ may have linkers 26 attached to one or
both strands 18 and/or 20 at each of the opposed ends. In an example, the modified
dsNA 16’ is in an ionic salt buffer solution, such as saline citrate at milli-molar to molar
concentrations.
When using the kit, a user can deposit the polymer solution on the electronic
components, allow the polymer solution to remain on the electronic components for a
suitable time for the linkers 26 to attach to the respective electrodes 12, 14, and then
the electronic component may be rinsed with a suitable buffer to remove non-bound
modified dsNA 16’.
In addition to containing components to form the sensor 10, some examples
of the kit may also include a reagent solution that is to be used with the sensor 10. The
reagent solution includes labeled nucleotides, which are described in reference to Fig.
Referring now to Fig. 2, an example of a labeled nucleotide 30, which
includes the switch strand 28 mentioned above, is depicted. The labeled nucleotide 30
includes a nucleotide 32, a linking molecule 34 attached to a phosphate group of the
nucleotide 22, and the switch strand 28 attached to the linking molecule 34, the switch
strand 28 including a strand of nucleotides including bases 36 complementary to at
least some of the plurality of nucleotide bases 24 exposed at the gap 22 of the sensor
. The labeled nucleotide 30 may be considered a non-natural or synthetic nucleotide
because it is structurally or chemically distinct from a natural nucleotide.
The nucleotide 32 of the labeled nucleotide 30 may be a natural nucleotide.
Natural nucleotides include a nitrogen-containing heterocyclic base, a sugar, and three
or more phosphate groups. Examples of natural nucleotides include, for example,
ribonucleotides or deoxyribonucleotides. As mentioned above, in a ribonucleotide, the
sugar is a ribose, and in a deoxyribonucleotide, the sugar is a deoxyribose. In an
example, the nucleotide 32 is in the polyphosphate form because it includes several
phosphate groups (e.g., tri-phosphate, tetra-phosphate, penta-phosphate, hexa-
phosphate, etc.). The heterocyclic base (i.e., nucleobase) can be a purine base (e.g.,
adenine (A) or guanine (G)) or a pyrimidine base (e.g., cytosine (C), thymine (T), and
uracil (U)).
The labeled nucleotide 30 also includes the linking molecule 34. The linking
molecule 34 may be any long chain molecule that can chemically bond, at one end, to
the phosphate group(s) of the nucleotide 32 and that can chemically bond, at the other
end, to the switch strand 28. The linking molecule 34 may also be selected so that it will
not interact with a polymerase 38 used in the system 40, 40’ (see Figs. 4 and 5)
disclosed herein. The linking molecule 34 is selected so that it is long enough to permit
the switch strand 28 to associate with the nucleotide bases 24 exposed at the gap 22 of
the electrical sensor 10 while, for example, the nucleotide 32 is held by the polymerase
As examples, the linking molecule 34 may include an alkyl chain, a
poly(ethylene glycol) chain, an amido group, a phosphate group, a heterocycle such as
a triazole, nucleotides, or combinations thereof. Examples of the alkyl chain may
include at least 6 carbon atoms and examples of the poly(ethylene glycol) chain may
include at least 3 ethylene glycol units.
The following example illustrates an example of the labeled nucleotide 30,
where the linking molecule 34 comprises an alkyl chain, an amide group, a
poly(ethylene glycol) chain, and a triazole:
Switch Strand
The following example illustrates another example of the labeled nucleotide 30, where
the linking molecule 34 comprises alkyl chains, an amide group, poly(ethylene glycol)
chains, a triazole, and a phosphate group:
Switch Strand
The following example illustrates yet another example of the labeled nucleotide 30,
where the linking molecule 34 comprises alkyl chains, amide groups, poly(ethylene
glycol) chains, a triazole, and a phosphate group:
Switch Strand
The following example illustrates still a further example of the labeled nucleotide 10,
where the linking molecule 14, 14’ comprises an alkyl chains, an amide group,
poly(ethylene glycol) chains, a triazole, a phosphate group and a polynucleotide chain:
Switch Strand
While several example linking molecules 34 have been described, it is to be
understood that other linking molecules 34 may be used.
The switch strand 28 is a strand of nucleotides. The nucleotides in the switch
strand 28 are similar to the nucleotide 32, i.e., they include the nitrogen containing
heterocyclic base, the sugar, and three or more phosphate groups. At least some of the
nucleotides in the switch strand 28 include bases 36 that are complementary to the
bases 24 that are exposed at the gap 22 of the sensor 10. As such, the sequence of
the nucleotides in the switch strand 28 depends, at least in part, on the sequence of the
exposed bases 24.
In one example, the bases 36 in the switch strand 28 are completely
complementary to the plurality of nucleotide bases 24 exposed at the gap 22. As an
example, the nucleotide bases 24 exposed at the gap 22 may be G-G-G-G-G-G-G, and
the switch strand 28A may be C-C-C-C-C-C-C. As another example, the nucleotide
bases 24 exposed at the gap 22 may be G-A-G-T-G-C-G-G, and the switch strand 28A
may be C-T-C-A-C-G-C-C. In example shown in Fig. 3A, any suitable sequence may
be used for the switch strand 28A, as long as it has the same number of bases as, and
is completely complementary to, the bases 24 exposed at the gap 22. An example of
the labeled nucleotide 30A including a completely complementary switch strand 28A is
shown in Fig. 3A. As depicted, the switch strand 28A of the labeled nucleotide 30A
associates itself with the nucleotide bases 24 exposed at the gap 22. More specifically,
in this example, each of the nucleotide bases 36 in the switch strand 28A temporarily
and at least partially hybridizes to its complementary base 24 (of the polynucleotide
chain 20) that is exposed at the gap 22 in the polynucleotide chain 18. In some
examples, the hybridization is not complete, and in other examples, the hybridization is
complete. To achieve partial or complete hybridization, the melting temperature of the
interaction between the complementary bases can be tuned. Different degrees of
hybridization between different switch strands 28A and nucleotide bases 24 enables
different time signatures to be achieved with different switch strands 28A. When
incorporated, the switch strand 28A closes a switch of the modified dsNA 16’, which
significantly changes (e.g., increases) the conductivity of the dsNA 16’, modulates the
channel 16, and results in a detectable change.
In another example, the bases 36 in the switch strand 28 are not completely
complementary to the plurality of nucleotide bases 24 exposed at the gap 22; but rather,
the switch strand 28B includes at least one nucleotide having a mismatched base 42
that is non-complementary to a corresponding one (shown as 24’) of the plurality of
nucleotide bases 24 exposed at the gap 22, as shown in Fig. 3B. In other words, the
mismatched base 42 is not complementary to the corresponding nucleotide base 24’
exposed at the gap 22. As an example, the nucleotide bases 24 exposed at the gap 22
may be G-G-G-G-G-G-G, and the switch strand 28B may be C-C-C-A-C-C-C. In this
example, the adenine of the switch strand 28B is the mismatched base 42 because it is
not complementary to the corresponding guanine exposed at the gap 22 of the
polynucleotide chain 20. As another example, the nucleotide bases 24 exposed at the
gap 22 may be G-A-G-T-G-C-G-G, and the switch strand 28B may be C-C-C-A-C-G-C-
C. In this example, the second cytosine of the switch strand 28B is the mismatched
base 42 because it is not complementary to the corresponding adenine exposed at the
gap 22 of the polynucleotide chain 20. In the example shown in Fig. 3B, any suitable
sequence may be used for the switch strand 28B, as long as it has the same number of
bases as, is partially complementary to, and includes at least one mismatched base to
the bases 24 exposed at the gap 22. As depicted, the switch strand 28B of the labeled
nucleotide 30B associates itself with the nucleotide bases 24 exposed at the gap 22.
More specifically, in this example, while some of the nucleotide bases 36 in the switch
strand 28B temporarily hybridize to respective complementary bases 24, the
mismatched base 42 and the corresponding nucleotide base 24’ in the polynucleotide
chain 20 remain unbound. When incorporated, the switch strand 28B substantially
closes a switch of the modified dsNA 16’ (but does not fully close the switch due to the
mismatched base 42), which significantly changes (e.g., increases) the conductivity of
the dsNA, 16’, modulates the channel 16, and results in a detectable change. It is to be
understood that, in some examples, the conductivity increase with switch strand 28B
may not be as large as the increase observed with the switch strand 28A, due to the
mismatched base 42.
In yet another example, the strand of nucleotides in the switch strand 28 has
at least one nucleotide fewer than the plurality of nucleotide bases 24 exposed at the
gap 22. An example of this switch strand 28C is shown in Fig. 3C. The nucleotides in
the switch strand 28C are complementary to some of the nucleotide bases 24 exposed
at the gap 22; however, after the switch strand 28C is associated at the gap 22, at least
one of the nucleotide bases 24’’ remains unbound because of the shorter switch strand
length (due to the missing bases). As an example, the nucleotide bases 24 exposed at
the gap 22 may be G-G-G-G-G-G-G, and the switch strand 28C may be C-C-C-C-C. In
this example, the switch strand 28C is missing two bases, or is two nucleotides shorter
than the total number of nucleotide bases 24 (including 24’’) exposed at the gap 22. As
another example, the nucleotide bases 24 exposed at the gap 22 may be G-A-G-T-G-C-
G-G, and the switch strand 28C may be T-C-A-C-G-C-C. In this example, the switch
strand 28C is missing one base, or is one nucleotide shorter than the total number of
nucleotide bases 24 (including 24’’) exposed at the gap 22. In the example shown in
Fig. 3C, any suitable sequence may be used for the switch strand 28C, as long as it has
fewer than the total number of bases 24 exposed at the gap 22 and is complementary to
some of the bases 24 exposed at the gap 22. As depicted in Fig. 3C, when the switch
strand 28C of the labeled nucleotide 30C associates itself at the gap 22, i) the
nucleotide bases 36 in the switch strand 28C temporarily and at least partially hybridize
to respective complementary bases 24, and ii) some of the nucleotide bases 24’’ in the
polynucleotide chain 20 remain unbound because the switch strand 28 is missing
bases. When incorporated, the switch strand 28C substantially closes a switch of the
modified dsNA 16’ (but does not fully close the switch due to the missing base(s)),
which significantly changes (e.g., increases) the conductivity of the modified dsNA 16’
(and the channel 16) and results in a detectable change. It is to be understood that, in
some examples, the conductivity increase with switch strand 28C may not be as large
as the increase observed with the switch strand 28A, due to the missing bases.
In still another example, the strand of nucleotides in the switch strand 28 has
a higher number of nucleotides than the plurality of nucleotide bases 24 exposed at the
gap 22, and a portion of the switch strand 28 forms a stem loop when associated at the
gap 22. An example of this switch strand 28D is shown in Fig. 3D. Some of the
nucleotides in the switch strand 28D are complementary to the nucleotide bases 24
exposed at the gap 22; however, after the switch strand 28D is associated at the gap
22, non-complementary nucleotides 36’ of the switch strand 28C remain unbound and
form the stem loop 44. As an example, the nucleotide bases 24 exposed at the gap 22
may be G-G-G-G-G-G-G-G-G, and the switch strand 28C may be C-C-C-C. In this
example, the switch strand 28D includes nine additional bases 36’ that forms a stem
loop 44. As another example, the nucleotide bases 24 exposed at the gap 22 may be
A-G-T-T-T-T-T-T-G, and the switch strand 28C may be T-C-C. In this example, the
switch strand 28C includes six additional bases 36’ that forms a stem loop 44. In the
example shown in Fig. 3D, any suitable sequence may be used for the switch strand
28C, as long as it has more than the total number of bases 24 exposed at the gap 22
and includes at least some nucleotide bases that are complementary to the bases 24
exposed at the gap 22. The nucleotide bases at either end of the stem loop 44 may be
completely complementary to the nucleotide bases 24 exposed at the gap 22, may
include one or more non-complementary bases, may have missing bases, or may
include combinations of complementary, non-complementary, and missing bases. As
depicted in Fig. 3D, when the switch strand 28D of the labeled nucleotide 30D
associates itself at the gap 22, i) some of the nucleotide bases 36 in the switch strand
28D temporarily and at least partially hybridize to respective complementary bases 24,
and ii) some of the non-complementary nucleotide bases 36’’ in the switch strand 28D
remain unbound and form the stem loop 44. When incorporated, the switch strand 28D
closes a switch of the modified dsNA 16’, which significantly changes (e.g., increases)
the conductivity of the modified dsNA 16’, modulates the channel 16, and results in a
detectable change. Some of the electronic current is going to be carried on either chain
18, 20 (e.g., when both chains 18, 20 are bound to the electrodes 12, 14), so adding a
stem loop 44 is comparable to adding a larger resistor in parallel.
Any example of the labeled nucleotides 30 (e.g., 30A, 30B, 30C, 30D)
disclosed herein may be used in a reagent solution of an example of the kit, and/or in a
sensing system 40, 40’, examples of which is shown in Figs. 4 and 5. Each of the
systems 40, 40’ also includes an example of the sensor 10 disclosed herein.
The example of the sensing system 40 shown in Fig. 4 includes a flow cell 41
and an electronic sensor 10 integrated into the flow cell 41. The electronic sensor 10
includes two electrodes 12, 14; a modified, partially double stranded nucleic acid
polymer 16 bridging the two electrodes 12, 14, the modified, partially double stranded
nucleic acid polymer 16 including two polynucleotide chains 18, 20 partially bonded (via
hydrogen bonding) together, a gap 22 in a first 18 of the polynucleotide chains wherein
nucleotides are missing; and a plurality of nucleotide bases 24 of a second 20 of the
polynucleotide chains exposed at the gap 22. The flow cell 41 is a vessel that contains
the sensor 10. It is to be understood that other vessels, such as a well, tube, channel,
cuvette, Petri plate, bottle, or the like may alternatively contain the sensor 10. Cyclic
processes, such as nucleic acid sequencing reactions, are particularly well suited for
flow cells 41.
Example flow cells 41 include a substrate/support 13 and a lid bonded directly
or indirectly thereto or integrally formed therewith. Flow cell 41 may include a fluid inlet
45 and a fluid outlet 47 that enable delivery of bulk reagents to one sensor 10 or an
array of sensors 10 contained within the flow cell 41.
The sensing system 40 may also include a reagent delivery system 49 to
selectively introduce a reagent to an input (e.g., fluid inlet 45) of the flow cell 41, over
the sensor 10, and then out of the fluid outlet 47. The reagent delivery system 49 may
include tubing or other fluidics that can permanently or removably attach to the fluid inlet
45. The reagent deliver system 49 may include a sample container 51. The reagent
(including the labeled nucleotide 30 to be introduced to the electronic sensor 10) may
be stored in the sample container or prepared and introduced to the sample container
just before use. The reagent deliver system 49 may also include a pump or other
suitable equipment to retrieve the reagent from the sample container 51 and deliver it to
the fluid inlet 45. In other examples, the sample container 51 is positioned so the
reagent can flow by gravity to the fluid inlet 45, over the sensor 10, and out the fluid
outlet 47.
The sensor 10 in the flow cell 41 may also be operatively connected to a
detector 15 to detect conductivity changes of the sensor 10 when the sensing system
40 is used.
Another example of the system 40’ is shown in Fig. 5 and includes an
electronic sensor 10, which includes two electrodes 12, 14; a modified, partially double
stranded nucleic acid polymer 16 bridging the two electrodes 12, 14, the modified,
partially double stranded nucleic acid polymer 16 including two polynucleotide chains
18, 20 partially bonded (via hydrogen bonding) together, a gap 22 in a first 18 of the
polynucleotide chains wherein nucleotides are missing; and a plurality of nucleotide
bases 24 of a second 20 of the polynucleotide chains exposed at the gap 22; and
separate reagents that are to be introduced to the electronic sensor 10, the reagents
including labeled nucleotides 30, at least one of the labeled nucleotides 30 including a
nucleotide 32, a linking molecule 34 attached to a phosphate group of the nucleotide, a
switch strand 28 attached to the linking molecule 34, the switch strand 28 including a
strand of nucleotides including bases 36 complementary to at least some of the plurality
of nucleotide bases 24 exposed at the gap 22. In the example shown in Fig. 5, the
polynucleotide chain 18 is ACCGGGGTA-gap-ATCCG and the polynucleotide chain 20
is TGGGCCCCATCCCCCCTAGGC (SEQ. ID No. 1). In the polynucleotide chain 20,
the nucleotide bases “CCCCCC” are exposed at the gap 22 (at least until a switch
strand 28 is associated therewith).
While not shown, it is to be understood that the sensor 10 may be positioned
within or part of a vessel, such as flow cell 41 (Fig. 4), a tube, channel, cuvette, Petri
plate, bottle, or the like. Another example of a suitable vessel is a flow cell.
While one sensor 10 is shown in Fig. 5, it is to be understood that the sensing
system 40’ may include an array of sensors 10 positioned on a substrate. Moreover,
the sensor(s) 10 of the sensing system 40’ may each be electrically connected to a
respective detector 15 to detect a response from the electrical sensor 10 when the
switch strand 28 is associated at the gap 22.
Some examples of the sensing system 40’ further include a polymerase 38
anchored to the modified dsNA 16’, and a template polynucleotide chain 48 that is to be
introduced to the sensor 10.
As shown in Fig. 5, the sensor 10 includes the polymerase 38. Any DNA
polymerase may be used that can catalyze the addition of one nucleotide at a time to
the nascent strand. The DNA polymerase may be from any of the following families: A,
B, C, D, X, Y, and RT. Specific examples from family A include T7 DNA polymerase,
Pol I, Pol γ, Pol Θ, or Pol v; or from family B include Pol II, Pol B, Pol ζ, Pol α, Pol δ, and
Pol ε; or from family C include Pol III; or from family D include Pol D (DP1/DP2
heterodimer), or from family X include Pol β, Pol σ, Pol λ, Pol μ, and Terminal
deoxynucleotidyl transferase; or from family Y include Pol ι, Pol κ, Pol η, Pol IV, and Pol
V; or from family RT include Telomerase.
As shown in Fig. 5, the polymerase 38 is immobilized to the modified dsNA
16’ with a tether 46. In another example, the polymerase 38 is immobilized to a
substrate with the tether 46. The tether 46 is used as an anchor for the polymerase 38,
and it may be desirable that the tether 46 be non-conducting. A non-conducting tether
may be particularly desirable when the polymerase 38 is attached to the modified dsNA
16’. Examples of a suitable tether 46 includes polyethylene glycol (PEG) with a
cleavable link at some point along the PEG chain, or may include Nickel NTA/His tag
chemistry, streptavidin/biotin chemistry (e.g., streptavidin attached to the modified dsNA
16’ and biotin attached to the polymerase 38), DNA-DNA hybridization, DNA-PNA
hybridization, carboxyl silane 1-ethyl(3-dimethylaminopropyl)carbodiimide (EDC), or
any other suitable linker that can attach the polymerase to the modified dsNA 16’ or to
the substrate surface. In some examples, the tether 46 holds the polymerase 38 at
least 10 nm away from the modified dsNA 16’. This may be desirable, for example, so
that conformal changes to the polymerase 38, charges of the polymerase 38, and/or
charges of the target/template polynucleotide chain 48 held by the polymerase 38 do
not interfere with the sensing operation of the modified dsNA 16’.
In an example, the modified dsNA 16’ may be initially attached to the
polymerase 38 by the tether 46, which includes a cleavable link. This combination may
be introduced to the electrodes 12, 14 to attach the opposed ends of the modified dsNA
16’ to the electrodes 12, 14 and to attach the polymerase 38 to a substrate surface via,
e.g., Nickel NTA/His tag chemistry. In this example, the cleavable link may be cleaved
to detach the polymerase 38 from the modified dsNA 16’. In this example, the
polymerase 38 is in proximity to the modified dsNA 16’, but is not actually touching it. It
is to be understood that the tether 46 may be cleaved when chemistry is provided to
hold the polymerase 38, e.g., on the substrate surface and within proximity to the
sensor 10.
As mentioned herein, examples of the system 40, 40’ may also include the
template polynucleotide chain 48 that is to be introduced to the sensor 10.
The template polynucleotide chain 48 may be any sample that is to be
sequenced, and may be composed of DNA, RNA, or analogs thereof (e.g., peptide
nucleic acids). The source of the template (or target) polynucleotide chain 48 can be
genomic DNA, messenger RNA, or other nucleic acids from native sources. In some
cases, the template polynucleotide chain 48 that is derived from such sources can be
amplified prior to use in a method or system 40, 40’ herein. Any of a variety of known
amplification techniques can be used including, but not limited to, polymerase chain
reaction (PCR), rolling circle amplification (RCA), multiple displacement amplification
(MDA), or random primer amplification (RPA). It is to be understood that amplification
of the template polynucleotide chain 48 prior to use in the method or system 40, 40’ set
forth herein is optional. As such, the template polynucleotide chain 48 will not be
amplified prior to use in some examples. Template/target polynucleotide chains 48 can
optionally be derived from synthetic libraries. Synthetic nucleic acids can have native
DNA or RNA compositions or can be analogs thereof.
Biological samples from which the template polynucleotide chain 48 can be
derived include, for example, those from a mammal, such as a rodent, mouse, rat,
rabbit, guinea pig, ungulate, horse, sheep, pig, goat, cow, cat, dog, primate, human or
non-human primate; a plant such as Arabidopsis thaliana, corn, sorghum, oat, wheat,
rice, canola, or soybean; an algae such as Chlamydomonas reinhardtii; a nematode
such as Caenorhabditis elegans; an insect such as Drosophila melanogaster, mosquito,
fruit fly, honey bee or spider; a fish such as zebrafish; a reptile; an amphibian such as a
frog or Xenopus laevis; a dictyostelium discoideum; a fungi such as pneumocystis
carinii, Takifugu rubripes, yeast, Saccharamoyces cerevisiae or Schizosaccharomyces
pombe; or a plasmodium falciparum. Template polynucleotide chains 48 can also be
derived from prokaryotes such as a bacterium, Escherichia coli, staphylococci or
mycoplasma pneumoniae; an archae; a virus such as Hepatitis C virus, ebola virus or
human immunodeficiency virus; or a viroid. Template polynucleotide chains 48 can be
derived from a homogeneous culture or population of the above organisms or
alternatively from a collection of several different organisms, for example, in a
community or ecosystem.
Moreover, template polynucleotide chains 48 may not be derived from natural
sources, but rather can be synthesized using known techniques. For example, gene
expression probes or genotyping probes can be synthesized and used in the examples
set forth herein.
In some examples, template polynucleotide chains 48 can be obtained as
fragments of one or more larger nucleic acids. Fragmentation can be carried out using
any of a variety of techniques known in the art including, for example, nebulization,
sonication, chemical cleavage, enzymatic cleavage, or physical shearing.
Fragmentation may also result from use of a particular amplification technique that
produces amplicons by copying only a portion of a larger nucleic acid chain. For
example, PCR amplification produces fragments having a size defined by the length of
the nucleotide sequence on the original template that is between the locations where
flanking primers hybridize during amplification. The length of the template
polynucleotide chain 48 may be in terms of the number of nucleotides or in terms of a
metric length (e.g., nanometers).
A population of template/target polynucleotide chains 48, or amplicons
thereof, can have an average strand length that is desired or appropriate for a particular
application of the methods or system 40, 40’ set forth herein. For example, the average
strand length can be less than about 100,000 nucleotides, about 50,000 nucleotides,
about 10,000 nucleotides, about 5,000 nucleotides, about 1,000 nucleotides, about 500
nucleotides, about 100 nucleotides, or about 50 nucleotides. Alternatively or
additionally, the average strand length can be greater than about 10 nucleotides, about
50 nucleotides, about 100 nucleotides, about 500 nucleotides, about 1,000 nucleotides,
about 5,000 nucleotides, about 10,000 nucleotides, about 50,000 nucleotides, or about
100,000 nucleotides. The average strand length for a population of target
polynucleotide chains 48, or amplicons thereof, can be in a range between a maximum
and minimum value set forth above.
In some cases, a population of template/target polynucleotide chains 48 can
be produced under conditions or otherwise configured to have a maximum length for its
members. For example, the maximum length for the members can be less than about
100,000 nucleotides, about 50,000 nucleotides, about 10,000 nucleotides, about 5,000
nucleotides, about 1,000 nucleotides, about 500 nucleotides, about 100 nucleotides or
about 50 nucleotides. Alternatively or additionally, a population of template
polynucleotide chains 48, or amplicons thereof, can be produced under conditions or
otherwise configured to have a minimum length for its members. For example, the
minimum length for the members can be more than about 10 nucleotides, about 50
nucleotides, about 100 nucleotides, about 500 nucleotides, about 1,000 nucleotides,
about 5,000 nucleotides, about 10,000 nucleotides, about 50,000 nucleotides, or about
100,000 nucleotides. The maximum and minimum strand length for template
polynucleotide chains 48 in a population can be in a range between a maximum and
minimum value set forth above.
As shown in Fig. 5, the template polynucleotide chain 48 (e.g., a single
stranded DNA strand) to be sequenced is bound to the polymerase 38 after having
been introduced in solution along with reagents, such as the labeled nucleotides 30.
In some examples, several different labeled nucleotides 30 (e.g., respectively
labeled with dA, dC, dG, and dT as the nucleotide 32) may be used together in a
system 40, 40’ including an array of sensors 10. In one example, four different labeled
nucleotides 30 are used, each including a different nucleotide 32 and a different
nucleotide-specific switch strand 28. As an example, the labeled nucleotides 30 include
a first labeled nucleotide, which includes deoxyadenosine polyphosphate as the
nucleotide and a first nucleotide-specific switch strand; a second labeled nucleotide,
which includes deoxyguanosine polyphosphate as the nucleotide and a second
nucleotide-specific switch strand having a different sequence than the first switch
strand; a third labeled nucleotide, which includes deoxycytidine polyphosphate as the
nucleotide and a third nucleotide-specific switch strand having a different sequence than
each of the first and second switch strands; and a fourth labeled nucleotide, which
includes deoxythymidine polyphosphate as the nucleotide and a fourth nucleotide-
specific switch strand having a different sequence than each of the first, second, and
third switch strands. As such, in this example, the first, second, third, and fourth
nucleotide-specific switch strands are different from each other. The different switch
strands will generate different conductivity changes (when associated at a
complementary gap 22), which may be used to identify the specific nucleotide attached
thereto.
Referring now to Fig. 6, an example of a method is depicted. The method
100 includes introducing a template polynucleotide chain 48 to an electronic sensor 10
having a polymerase 38 tethered to i) a modulatable electrically conductive channel 16
that bridges a space between, and is electrically connected to two electrodes 12, 14, or
ii) a substrate 13 supporting the two electrodes 12, 14, the modulatable electrically
conductive channel 16 including a modified, partially double stranded nucleic acid
polymer 16’, which includes: two polynucleotide chains 18, 20 partially bonded together;
a gap 22 in a first of the polynucleotide chains 18 wherein nucleotides are missing; and
a plurality of nucleotide bases 24 of a second of the polynucleotide chains 20 exposed
at the gap 22 in the first of the polynucleotide chains 18 (reference numeral 102);
introducing reagents including labeled nucleotides 30 to the electronic sensor 10,
whereby a nucleotide 32 of one of the labeled nucleotides associates with the
polymerase 38 and a nucleotide-specific switch strand 28 of the one of the labeled
nucleotides 30 associates with at least some of the plurality of nucleotide bases 24
exposed at the gap 22 (reference numeral 104); and in response to the association at
the gap 22, detecting a response of the electronic sensor 10. Fig. 5 will also be
referenced throughout the discussion of the method 100.
As shown in Fig. 5, the template polynucleotide chain 48 introduced to the
sensor 10 may be held in place by the polymerase 38, which is tethered to the sensor
or to a substrate surface that supports the sensor 10. The template polynucleotide
chain 48 shown in Fig. 5 is a template strand of DNA. The template polynucleotide
chain 48 may be introduced in a biologically stable solution, along with reagents, such
as the labeled nucleotides 30. The biologically stable solution may be any buffer
suitable for polymerase base incorporation reactions, such as polymerase chain
reaction (PCR) or linear amplification. As an example, biologically stable solution may
include a buffer having a pH near 7, a salt concentration above several millimolar, and
Mg ions at millimolar concentration.
Also as shown in Fig. 5, the labeled nucleotide 30 may include a base that is
complementary to a target nucleic acid of the template polynucleotide chain 48. The
labeled nucleotide 30 will be held in place, in part, by the polymerase 38 that is also
bound to the template polynucleotide chain 48.
The interaction between the labeled nucleotide 30 and polymerase 38 and the
length of the linking molecule 34 enable the switch strand 28 to associate with the gap
22 of the sensor 10. In an example, the association of the switch strand 28 with the gap
22 involves hybridization of at least a portion of the switch strand 28 with the nucleotide
bases 24 exposed at the gap 22. The hybridization that takes place will depend, in part,
upon the switch strand 28 (e.g., 28A, 28B, 28C, 28D) that is used. The temperature
and/or ion concentration of the solution may be adjusted in order to initiate or promote
the complete or partial hybridization or annealing of the switch strand 28 to at least
some of the nucleotide bases 24 exposed at the gap 22. As one example, the switch
strand 28 may be designed to partially or completely hybridize at the gap 22 at room
temperature (e.g., from about 18°C to about 22°C) and in a solution having a 50 mM
salt concentration.
The polymerase 38 will hold the switch strand 28 in proximity to the gap 22,
thus allowing several hybridization and de-hybridization events to occur. In contrast, a
random strand drifting by will likely hybridize once and then drift away. The switch
strand 28 may be held in proximity to the gap 22 until it is disassociated, for example,
using melting or another suitable technique. In some instances, the association of the
switch strand in the gap 22 may be up to tens of milliseconds, or longer. This relatively
long interaction turns the switch “ON” (e.g., modulate the channel 16 by increasing the
conductance from the lower state) and the change in conductivity can be detected. This
relatively long interaction is unlike other labeled nucleotides 30 present in the solution
(i.e., the random, drifting strand), which may diffuse and briefly touch, but not undergo
several at least partial hybridization and de-hybridization events at the sensor 10. The
brief interaction of these other labeled nucleotides 30 may cause a short-lived and/or
sporadic conductivity change, and thus is distinguishable from the conductivity change
that results from the switch strand 28 being held in proximity to the gap 22.
When the switch strand 28 does at least partially hybridize and de-hybridize
several times to the exposed nucleotide bases 24, the response of the sensor 10 may
be indicative of the base of the labeled nucleotide 30 because the switch strand 28 is
nucleotide-specific (i.e., a specific switch strand 28 is selected for a specific base). As
such, the method 100 may also involve associating the response of the sensor 10 with
the associated nucleotide-specific switch strand 28 (i.e., the labeled nucleotide 30 that
has associated with the polymerase 38 and the gap 22), and based on the nucleotide-
specific switch strand 28, identifying the nucleotide (e.g., the base) of the associated
labeled nucleotide 30 (i.e., the labeled nucleotide 30 that has associated with the
polymerase 38 and the gap 22).
The base of the associated labeled nucleotide 30 will be incorporated into a
nascent strand 50 that is hybridized to the template polynucleotide chain 48. This will,
in turn, break the bond between the phosphate group(s) of the labeled nucleotide 30
and the newly incorporated nucleotide base. This cleaves the remainder of the labeled
nucleotide 30 from the newly incorporated nucleotide base.
Since the switch strand 28 may prefer to be at least partially hybridized and
stay connected in the double helix configuration of the modified dsNA 16’, the method
100 may further involve heating to disassociate the nucleotide-specific switch strand 28
from the gap 22. The melting temperature of the switch strand 28 may be tuned when
synthesizing the labeled nucleotide 30 to make the “ON” time shorter or longer,
depending, in part, on how long the polymerase 38 holds the nucleotide 32 of the
labeled nucleotide 30. In an example, the melting temperature may be tuned to
correspond with the temperature at which the sensing system 40, 40’ is operated when
the bond between the phosphate group(s) of the labeled nucleotide 30 and the newly
incorporated nucleotide base. This would cause the dissociation of the switch strand 28
within the same time frame of when the labeled nucleotide 30 is cleaved. In another
example, it may be desirable for the “OFF” time of the switch strand 28 to be much
shorter than the time that the labeled nucleotide 30 is held by the polymerase 28 during
incorporation into the nascent strand 50. This may minimize background events from
the switch strands 28 that are not associated with the polymerase 28.
As a result of cleavage and disassociation, the remainder of the labeled
nucleotide 30 is free to dissociate from the nucleotide base and diffuse away from the
sensor 10. Cleavage and disassociation again modulates the channel 16, by returning
the conductivity of the sensor 10 to the initial (e.g., lower) conductivity state it was in
before the association of the labeled nucleotide 30 with the polymerase 38 and with the
gap 22. The appearance and disappearance of signal as the conductivity of the sensor
changes (e.g., increases and returns to the lower state), respectively, can be
correlated with the incorporation of a nucleotide base into the nascent strand 50 of the
template nucleotide chain 48 and the subsequent dissociation of the labeled nucleotide
In the example method 100, the associating of the one of the labeled
nucleotides 30 (with the polymerase 32 and the gap 22), the detecting, the associating
of the response, and the identifying together may be used for single molecule detection
of a polymerase incorporation event (i.e., which nucleotide has been incorporated into
the nascent strand 50).
It should be appreciated that all combinations of the foregoing concepts and
additional concepts discussed in greater detail below (provided such concepts are not
mutually inconsistent) are contemplated as being part of the inventive subject matter
disclosed herein. In particular, all combinations of claimed subject matter appearing at
the end of this disclosure are contemplated as being part of the inventive subject matter
disclosed herein. It should also be appreciated that terminology explicitly employed
herein that also may appear in any disclosure incorporated by reference should be
accorded a meaning most consistent with the particular concepts disclosed herein.
Reference throughout the specification to “one example”, “another example”,
“an example”, and so forth, means that a particular element (e.g., feature, structure,
and/or characteristic) described in connection with the example is included in at least
one example described herein, and may or may not be present in other examples. In
addition, it is to be understood that the described elements for any example may be
combined in any suitable manner in the various examples unless the context clearly
dictates otherwise.
The terms “substantially” and “about” used throughout this disclosure,
including the claims, are used to describe and account for small fluctuations, such as
due to variations in processing. For example, they can refer to less than or equal to
±5%, such as less than or equal to ±2%, such as less than or equal to ±1%, such as
less than or equal to ±0.5%, such as less than or equal to ±0.2%, such as less than or
equal to ±0.1%, such as less than or equal to ±0.05%.
Furthermore, it is to be understood that the ranges provided herein include
the stated range and any value or sub-range within the stated range, as if they were
explicitly recited. For example, a range represented by from about 10 nm to about 50
nm, should be interpreted to include not only the explicitly recited limits of from about 10
nm to about 50 nm, but also to include individual values, such as about 15 nm, 22.5 nm,
45 nm, etc., and sub-ranges, such as from about 20 nm to about 48 nm, etc.
While several examples have been described in detail, it is to be understood
that the disclosed examples may be modified. Therefore, the foregoing description is to
be considered non-limiting.
Claims (28)
1. A sensor, comprising: two electrodes having a space therebetween; and a modulatable electrically conductive channel attached to the two electrodes, the 5 modulatable electrically conductive channel including a modified, partially double stranded nucleic acid polymer electrically connected to the two electrodes and bridging the space between the two electrodes, the modified, partially double stranded nucleic acid polymer including: two polynucleotide chains partially bonded together; 10 a gap in a first of the polynucleotide chains wherein nucleotides are missing; and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains. 15
2. The sensor as defined in claim 1, wherein the gap has a length ranging from about 10 nm to about 50 nm.
3. The sensor as defined in any of claims 1 or 2, further comprising a polymerase attached to the modified, partially double stranded nucleic acid polymer.
4. The sensor as defined in any of claims 1 through 3, wherein: i) linkers respectively attach each end of the first of the polynucleotide chains to a respective one of the two electrodes; or ii) linkers respectively attach each end of the second of the polynucleotide chains 25 to a respective one of the two electrodes; or iii) both i and ii.
5. The sensor as defined in any of claims 1 through 4, wherein at least one of the plurality of nucleotide bases exposed at the gap is a guanine base.
6. The sensor as defined in any of claims 1 through 4, wherein each of the plurality of nucleotide bases exposed at the gap is a guanine base.
7. The sensor as defined in any of claims 1 through 6, further comprising a 5 detector to detect a response from the modified, partially double stranded nucleic acid polymer when a switch strand, including a strand of nucleotides including bases complementary to at least some of the plurality of nucleotide bases exposed at the gap, associates with the at least some of the plurality of nucleotide bases at the gap. 10
8. The sensor as defined in any of claims 1 through 7, further comprising: a substrate supporting the two electrodes; and a polymerase attached to the substrate.
9. The sensor as defined in any of claims 1 through 8, further comprising a 15 fluidic system to introduce a reagent to the modified, partially double stranded nucleic acid polymer.
10. The sensor as defined in claim 9 wherein the reagent includes labeled nucleotides, at least one of the labeled nucleotides including: 20 a nucleotide; a linking molecule attached to a phosphate group of the nucleotide; and a switch strand attached to the linking molecule, the switch strand including a strand of nucleotides including bases complementary to at least some of the plurality of nucleotide bases exposed at the gap.
11. The sensor as defined in any of claims 1 through 10, further comprising a plurality of other modulatable electrically conductive channels attached to the two electrodes, each of the other modulatable electrically conductive channels including a respective modified, partially double stranded nucleic acid polymer electrically 30 connected to the two electrodes and bridging the space between the two electrodes.
12. The sensor as defined in any of claims 1 through 10 wherein, the modulatable electrically conductive channel exhibits: a first conductance when the plurality of nucleotide bases are exposed at the gap; and 5 a second conductance that is different than the first conductance when at least some of the plurality of nucleotide bases at the gap are associated with complementary nucleotide bases.
13. A labeled nucleotide, comprising: 10 a nucleotide; a linking molecule attached to a phosphate group of the nucleotide; and a switch strand attached to the linking molecule, the switch strand including a strand of nucleotides including bases complementary to at least some of the plurality of nucleotide bases exposed at the gap of the sensor of any of claims 1 through 12.
14. A kit, comprising: an electronic component, including: a support; and two electrodes operatively disposed on the support and separated by a 20 space; and a polymeric solution, including: a liquid carrier; and a modified, partially double stranded nucleic acid polymer in the liquid carrier, the modified, partially double stranded nucleic acid polymer including: 25 two polynucleotide chains partially bonded together and having opposed ends; a linker attached to each of the opposed ends, each linker to attach to a respective one of the two electrodes; a gap in a first of the polynucleotide chains wherein nucleotides are 30 missing; and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains; the modified, partially double stranded nucleic acid polymer to form a modulatable electrically conductive channel in the space between the two electrodes 5 when each linker attaches to the respective one of the two electrodes.
15. The kit as defined in claim 14, further comprising a reagent solution including labeled nucleotides, at least one of the labeled nucleotides including: a nucleotide; 10 a linking molecule attached to a phosphate group of the nucleotide; and a switch strand attached to the linking molecule, the switch strand including a strand of nucleotides including bases complementary to at least some of the plurality of nucleotide bases exposed at the gap. 15
16. The kit as defined in claim 15, wherein the bases in the switch strand are completely complementary to the plurality of nucleotide bases exposed at the gap.
17. The kit as defined in claim 15, wherein the switch strand further includes at least one nucleotide having a mismatched base that is non-complementary to a 20 corresponding one of the plurality of nucleotide bases exposed at the gap.
18. The kit as defined in claim 15, wherein the strand of nucleotides in the switch strand has at least one nucleotide fewer than the plurality of nucleotide bases exposed at the gap.
19. The kit as defined in claim 15, wherein the strand of nucleotides in the switch strand has a higher number of nucleotides than the plurality of nucleotide bases exposed at the gap, and wherein a portion of the switch strand forms a stem loop when associated at the gap.
20. The kit as defined in claim 15, wherein: the strand of nucleotides in the switch strand has a higher number of nucleotides than the plurality of nucleotide bases exposed at the gap; a portion of the switch strand forms a stem loop when associated at the gap; and 5 an other portion of the switch strand is completely complementary to the plurality of nucleotide bases exposed at the gap or includes at least one nucleotide having a mismatched base that is non-complementary to a corresponding one of the plurality of nucleotide bases exposed at the gap. 10
21. A sensing system, comprising: a flow cell; and an electronic sensor integrated into the flow cell, the electronic sensor including: two electrodes having a space therebetween; a modulatable electrically conductive channel attached to the two 15 electrodes, the modulatable electrically conductive channel including a modified, partially double stranded nucleic acid polymer electrically connected to the two electrodes and bridging the space between the two electrodes, the modified, partially double stranded nucleic acid polymer including: two polynucleotide chains partially bonded together; 20 a gap in a first of the polynucleotide chains wherein nucleotides are missing; and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains. 25
22. The sensing system as defined in claim 21, further comprising a reagent delivery system to selectively introduce a reagent to an input of the flow cell.
23. The sensing system as defined in claim 22, wherein the reagent is in a sample container, and the reagent includes labeled nucleotides, at least one of the 30 labeled nucleotides including: a nucleotide; a linking molecule attached to a phosphate group of the nucleotide; and a switch strand attached to the linking molecule, the switch strand including a strand of nucleotides including bases complementary to at least some of the plurality of nucleotide bases exposed at the gap.
24. The sensing system as defined in any of claims 21 through 23, further comprising a detector to detect a response from the electronic sensor.
25. The sensing system as defined in any of claims 21 through 24, further 10 comprising a polymerase anchored to the modified, partially double stranded nucleic acid polymer or a support of the electronic sensor.
26. A method, comprising: introducing a template polynucleotide chain to an electronic sensor having a 15 polymerase tethered to i) a modulatable electrically conductive channel that bridges a space between, and is electrically connected to two electrodes or ii) a substrate supporting the two electrodes, the modulatable electrically conductive channel including a modified, partially double stranded nucleic acid polymer, which includes: two polynucleotide chains partially bonded together; 20 a gap in a first of the polynucleotide chains wherein nucleotides are missing; and a plurality of nucleotide bases of a second of the polynucleotide chains exposed at the gap in the first of the polynucleotide chains; introducing reagents including labeled nucleotides to the electronic sensor, 25 whereby a nucleotide of one of the labeled nucleotides associates with the polymerase and a nucleotide-specific switch strand of the one of the labeled nucleotides associates with at least some of the plurality of nucleotide bases exposed at the gap; and in response to the association at the gap, detecting a response of the electronic sensor.
27. The method as defined in claim 26, further comprising: associating the response of the electronic sensor with the associated nucleotide- specific switch strand; and based on the associated nucleotide-specific switch strand, identifying the 5 nucleotide of the one of the labeled nucleotides.
28. The method as defined in any of claims 26 or 27, further comprising heating to disassociate the nucleotide-specific switch strand from the gap.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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US62/692,468 | 2018-06-29 | ||
NLN2021376 | 2018-07-23 |
Publications (1)
Publication Number | Publication Date |
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NZ760030A true NZ760030A (en) |
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