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Multicolor Gold-Silver Nano-Mushrooms as Ready-to-Use SERS Probes for Ultrasensitive and Multiplex DNA/miRNA Detection Jing Su, Dongfang Wang, Lena Nörbel, Jianlei Shen, Zhihan Zhao, Yanzhi Dou, Tianhuan Peng, Jiye Shi, Sanjay Mathur, Chunhai Fan, and Shiping Song Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b04729 • Publication Date (Web): 25 Jan 2017 Downloaded from http://pubs.acs.org on January 26, 2017
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Analytical Chemistry
Multicolor Gold-Silver Nano-Mushrooms as Ready-to-Use SERS Probes for Ultrasensitive and Multiplex DNA/miRNA Detection ‖
‖
Jing Su, † Dongfang Wang, † Lena Nörbel,‡ Jianlei Shen,† Zhihan Zhao,† Yanzhi § Dou,† Tianhuan Peng,† Jiye Shi, Sanjay Mathur, *‡ Chunhai Fan† and Shiping Song*† †Division of Physical Biology & Bioimaging Center, Shanghai Synchrotron Radiation Facility, Shanghai Institute of Applied Physics, Chinese Academy of Sciences, Shanghai 201800, China ‡Institute of Inorganic Chemistry, University of Cologne, D-50939 Cologne, Germany §Kellogg College, University of Oxford, Oxford OX2 6PN, UK Corresponding Author *E-mail:
[email protected]. Tel: (86) 21 39194065. Fax: (86) 21 39194702. *E-mail:
[email protected]. Tel: (49) 221 4704107. Fax: (49) 221 4704899. ABSTRACT: Uniform silver-containing metal nanostructures with strong and stable surface-enhanced Raman scattering (SERS) signals hold great promise for developing ultrasensitive probes for biodetection. Nevertheless, the direct synthesis of ready-to-use such nanoprobes remain extremely challenging. Herein we report a DNA-mediated gold-silver nano-mushroom with interior nanogaps directly synthesized and used for multiplex and simultaneous SERS detection of various DNA and RNA targets. The DNA involved in the nanostructures can act as not only gap DNA (mediated DNA) but also probe DNA (hybridized DNA), and allow it have the inherent ability to recognize DNA and RNA targets. Importantly, we were the first establishing a new method for the generation of multicolor SERS probes using two different strategies. First Raman-labeled alkanethiol probe DNA was assembled on gold nanoparticles and second thiol-containing Raman reporters were co-assembled with the probe DNA. The ready-to-use probes also give great potential to develop ultrasensitive detection methods for various biological molecules.
INTRODUCTION
high-efficiency SERS probes for ultrasensitive
Surface enhanced Raman spectroscopy (SERS) has
detection of these biomolecular targets. One
been considered as a very powerful vibrational
challenge remains in the design of suitable and
spectroscopy technique which could give great
reproducible
potential for bio-detection, especially in the field of
because ‘hot spots’ existing in exterior nanogaps
SERS
active
nanostructures,13,14
For example it allows the detection
between metal nanostructures are usually randomly
of trace levels of analysts such as important
distributed leading to a wide distribution of
biomolecules like nucleic acids, proteins or small
enhancement factor values which goes ahead with
1-5
biomedicine.
Nevertheless,
a large variability and uncertainty in the SERS
there are still two main challenges to develop
signal15-18. Recently, more and more studies
6-12
molecules related to life sciences.
1
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focused on the generation of interior nanogaps.19-23
not like the gold-gold core-shell nanostructures
To address this problem, several approaches were
with fully closed interior nanogaps. The not fully
developed in our laboratory and others for the
closed gaps of nano-mushrooms cannot constantly
synthesis of gold core-shell nanostructures with a
hold small-molecule Raman reporters adsorbed
stable SERS signal.
24-27
onto the AuNPs.
The nanostructure was
provided with a polyA DNA induced interior
In this work, we developed multicolor gold-silver
nanogap which contains non-fluorescent small
(Au-Ag) nano-mushrooms which could be used as
molecule Raman reporters. We demonstrated that
ready-to-use SERS probes for ultrasensitive and
such gold-gold nanostructures could be employed
multiplex
for
SERS
oligonucleotides assembled on the AuNPs were
nanoprobes are strongly suitable and show some
redesigned, facilitating the formation of the interior
great advantages compared to other optical
nanogap
multiplex
detection
for
which
DNA/RNA
and
detection.
hybridization
with
First,
DNA/RNA
probes28. However, all such nanostructures only
targets.
can act as SERS “tags”, not SERS probes.29-31 That
surface of the nano-mushrooms easily guided
is, only after bio-functionalization, these SERS
hybridization with complementary strands.43,44
nanostructures can have the ability to hybridize or
Thus, the oligonucleotides can act as both gap
bind to biomolecular targets. The other challenge
DNA and probe DNA. Second, we designed a new
remains in synthesizing silver-containing metal
strategy
nanostructures with interior nanogaps. Silver has a
nano-mushrooms. The common strategy is the
larger SERS effect than gold and can be excited
assembly of Raman molecular labeled alkanethiol
over much broader wavelengths (from UV to IR)
probe
than gold.25,32 Ren and colleagues33 recently
Raman-reporter molecules can’t be labeled to
synthesized Au-Ag core-shell nanoparticles with
oligonucleotides, we were the first establishing a
embedded
internal
The oligonucleotides exposed on the
for
the
DNA
generation
on
AuNPs.
of
multicolor
Since
many
for
reliable
new protocol in which thiol containing Raman
After
further
reporters were co-assembled with the probe DNA.
bio-functionalization, the nanoparticles can be
Third, we demonstrated successful simultaneous
involved in biological applications. We developed
detection of the three virus DNA targets in one
a
synthesizing
sample, as each Raman reporter has its own unique
silver-containing bimetallic nano-mushrooms with
spectroscopic fingerprint. Also, the design of the
interior nanogaps.34 The oriented growth of silver
SERS nanoprobes could be effectively adapted for
on the surface of gold nanoparticles (AuNPs)
the detection of RNA.
quantitative
SERS
DNA-mediated
standards
40-42
analysis.
approach
for
modified with DNA leads to the formation of
EXPERIMENTAL SECTION
interior nanogaps between the silver cap and the
Reagents and materials
gold head in a size range of 1-2 nm. We could
AgNO3,
reach enhancement factors of about 109 orders of
modified with streptavidin (Dynabeads® My
respect to SERS enhancing effects34-37. Especially, different
nano-mushrooms
Raman
molecules
decorated could
and
Sigma-Aldrich (St. Louis, MO, USA). MMPs
introduction of silver which outperforms gold with Au-Ag
(ABT),
4-Nitrothiophenol (NBT) were purchased from
magnitude. This could also be contributed to the
the
4-Aminothiophenol
OneTM Streptavidin C1) were purchased from
with
Invitrogen (Carlsbad,CA, USA). Other reagents
display
including polyvinylpyrrolidone (K-30), (+)-sodium
well-defined Raman fingerprint peaks, thus they
L-ascorbate,
can serve as multicolor probes.38,39 However,
HAuCl4,
were
purchased
from
Sinopharm Chemical Reagent Co. Ltd (China).
multicolor nano-mushrooms are not easily obtained
HPLC-purified ssDNAs and RNAs were purchased
because the interior nanogap is partially opened,
from TaKaRa Biotechnology Co. Ltd (DaLian, 2
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Analytical Chemistry
China). NANO pure water (>18.0 MΩ, Milli-Q)
with vigorous vortexing for 1 min. Then the
was used in all experiments.
solutions were incubated for 0.5h. The particles
Preparation of DNA-modified AuNPs
were washed three times with 10 mM PB (pH 7.4) the
using centrifugation (7500 rpm, 7 min, 4 °C) and
oligonucleotide-coated AuNPs based on literature
re-suspended in 10mM PB buffer. The Au-Ag
We
modified
and
characterized
procedures. For the preparation of DNA-modified
nano-mushrooms were characterized with a TEM
AuNPs, HPLC purified SH decorated DNA was
(Tecnai G2F20S-TWIN, FEI, USA) and a UV-vis
mixed with 50nm AuNPs solutions. In detail, 10
spectrophotometer
µL of a 100µM DNA solution was mixed with a
Japan). The TEM samples were prepared by
50nm AuNPs solution (0.1 nM, 600µL). The
dropping the above solution (10 µL) onto a
resulting solution was placed on an orbital shaker
copper-coated
overnight at room temperature. The mixtures were
temperature, the samples were imaged using TEM.
adjusted to obtain a final phosphate concentration
SERS detection of DNA/RNA targets
of 10 mM (pH 7.4) with a 100mM phosphate
Capture-DNA-coated
buffer (PB). Next, the mixtures were adjusted to a
according to the manufacturer’s instructions.
final concentration of 0.1 M NaNO3 after the
Briefly, the MMPs modified with streptavidin were
addition of salting buffer (2 M NaNO3) every 1
first washed three times with washing buffer (10
hour for three times. Then the resulting solutions
mM sodium phosphate buffer with 0.15 M NaCl
were placed on an orbital shaker overnight at room
and 0.05% (v/v) Tween 20, pH 7.4) and
temperature. The solutions were then centrifuged at
re-suspended in 2 × B&W buffer (10 mM
7500 rpm for 7 min at 4 °C. The supernatants were
Tris-HCl, 1mM EDTA, 2 M NaCl, pH 7.5) to a
poured carefully to remove the unmodified DNA.
final concentration of 2µg/µL. For every 40µL
The precipitate was dispersed with 10 mM PB
2µg/ml beads, 2µL 100µM capture DNA was
solution (pH 7.4). These procedures were repeated
added. For the multiplex DNA/RNA markers
three times. Finally, the precipitate was dispersed
analysis, the mixture of 6µL biotinylated capture
with 600µL 10 mM PB (pH 7.4).
DNA/RNA (equal volume of the three kinds of
Preparation of DNA and Raman molecule co-modified AuNPs
DNA/RNA) was added. Similarly, the equal
The DNA-modified AuNPs (600µL) were mixed
the multiplex analysis. The solution was shaked
with 6µL of non-fluorescent small molecular
gently for 15 minutes at room temperature. Extra
Raman report solution (100mM, NBT, ABT) and
DNA/RNA was removed by washing three times
the mixture was incubated for 2 hours at room
with PBST and then magnetic beads were
temperature with gentle shaking. The particles
dispersed in PBS to the concentration of 0.2mg/ml.
were washed three times with 10 mM PB (pH 7.4)
For DNA/RNA detection assays, 10µL target
using centrifugation (7500 rpm, 7 min, 4 °C) to
DNA/RNA
remove excess Raman reporters. Then they were
incubated with MMPs at the same volume at 37°C
re-suspended in 600µL of 10 mM PB buffer (pH
for 2 hours. The solution was shaked gently in
7.4).
order to get the MMPs dispersed. Then extra
Synthesis and characterization of mushroom-like nanostructures
DNA/RNA target was removed by washing with
The modified AuNPs solution (100 µL, 0.1 nM)
functionalized Au-Ag SERS probes were added to
was first mixed with PVP (500 µL, 1%). Sodium
the solution and incubated for 2 hours at 37°C, and
ascorbate (30 µL, 20 mg/ml) was added, followed
the shaking state should be kept to avoid the
by the rapid addition of AgNO3 (30 µL, 0.001 M)
uncontrollable aggregation in the liquid phase.
45
(U-3010,
grid.
After
MMPs
Hitachi,
drying
were
Tokyo,
at
room
prepared
volume of targets of DNA/RNA was added during
with varying concentrations
was
PBST for three times. 0.2 nM of probe DNA
3
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After the reaction, the MMPs were washed with
mW. Raman scattering was collected at a spectral
PBST to remove extra SERS probes. MMPs were
resolution of 4 cm-1 with a charged-coupled device
collected and dispersed onto the silicon wafer.
CCD) camera. The MMPs sandwich complexes
Surface-Enhanced Raman scattering detection
samples were prepared by dropping 5µL of
SERS
using
complexes solutions on the silicon base. After
XPLORA (HORIBA, Jobin Yvon, France) Raman
drying at room temperature, the Raman spectra
microscope system. A Melles Griot He-Ne laser
reported here were collected for 10 exposure times
operating at λ=638nm was used as the excitation
in the range of 1000-2000 cm-1.
measurements
were
obtained
source with a laser power of approximately 10
Figure 1. a) TEM images of Au-Ag nano-mushrooms using AuNP seeds with the diameter of 50nm. b) The Au-Ag nano-mushrooms used as ready-to-use SERS nanoprobes for ”sandwich-type” DNA detection. c) SEM images of sandwich MMP complexes. Left: In the presence of target DNA (10 nM), a large number of 100 nm Au-Ag nano-mushrooms were coupled with the MMPs due to DNA hybridization. Right: The blank control experiment in which no DNA target was added. 4
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Analytical Chemistry
RESULTS AND DISCUSSION
(>90%). All of the Au-Ag nano-mushrooms have
Ready-to-use nano-mushrooms
an average size of 100 nm in diameter and a
Bimetallic nano-mushrooms with DNA-mediated
uniform interior nanogap (Figure 1a). In addition,
interior nanogap for high-efficiency SERS signal
the
amplification were previously developed in our
nano-mushrooms was characterized (Figure S1a),
UV-vis
spectrum
of
the
Au-Ag
Au-Ag
indicating that uniform nano-mushrooms were
nano-mushrooms increases with the size of gold
formed. Time-dependent Raman spectra indicated
seeds. The bigger the mushroom, the more DNA it
that the signal of the Au-Ag nano-mushrooms was
can load. Here we synthesized the Au-Ag
highly uniform and reproducible (Figure S1b),
nano-mushrooms
which arises from their highly uniform and stable
group.
34
The
SERS
with
signal
50nm
of
AuNPs.
The
structures of the Au-Ag nano-mushrooms were
nanogap-based
confirmed by transmission electron microscopy
nano-mushrooms dispersed in PB buffer should be
structures.
Note,
the
Au-Ag
(TEM) and UV-vis spectroscopy. For all of the
stored at 4 °C for three months without aggregation.
nano-mushroom types, highly uniform Au-Ag
Thus, compared with the SERS substrates made of
nanostructures at high yields were obtained. For
metal nanoparticles on the solid support,46-48 the
example, the X-rhodamine (ROX)-encoded Au-Ag
Au-Ag nano-mushrooms could show similar
nano-mushrooms were synthesized at a high yield
stability in the real application.
Figure 2. a) Dose–response SERS spectra for HAV target detection. b) Plot of SERS intensity at peak 1504 cm-1 as a function of logarithm of HAV DNA concentration. The concentration of HAV DNA ranged from 100 fM to 1 nM. c) SERS spectra of specific analysis for single base mismatch and non-cognate DNA. d) SERS intensity from HAV wild type DNA, HAV DNA with T mismatch, C mismatch, A mismatch, non-cognatic DNA and blank sample. Error bars indicate the standard deviations from 3 measurements. Error bars indicate the standard deviations from at least 3 measurements (Intensities shown were after background subtraction).
Besides
strong
SERS
signals,
the
DNA/RNA hybridization. As gold heads are
Au-Ag
nano-mushrooms have the inherent ability of
partially
covered
5
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hats
in
the
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nano-mushrooms, exposed oligonucleotides on the
decreased with HAV DNA concentration changed
gold heads are free and can readily hybridize to
from 100fM to 1nM.The SERS intensity versus
their complementary sequences, enabling the
HAV DNA concentration was plotted as a
Au-Ag
dose-response curve at selected peak (1504 cm-1
nano-mushrooms
to
be
ready-made
SERS-active probes for DNA detection. To
for ROX). It is obvious that the SERS signal could
evaluate the hybridization properties of Au-Ag
be observed at DNA target concentration as low as
nano-mushrooms,
universal
100 fM, which corresponds to 1 amol of DNA
analytical strategy for virus DNA marker (Figure
molecules in 10 µL sample (see Figure 2a,b). Also,
1b). We designed a specific oligonucleotide
we challenged the hybridization specificity of the
labelled with ROX which can act as both a
Au-Ag nano-mushrooms by designing different
mediated DNA for the synthesis of Au-Ag
types of mutation oligonucleotide sequences and a
nano-mushrooms and a probe DNA to recognize
noncognatic sequence (see Table S1 in Supporting
DNA fragments of hepatitis A virus (HAV) Vall7
Information for detailed sequences). As can be
polyprotein gene. After hybridizing to the Au-Ag
observed in Figure 2 (c, d), only the wild type
nano-mushrooms,
were
DNA target reached the highest SERS signal, while
micro-magnetic
the signals resulted from 1 µM of mutation
nanoparticles (MMPs) modified with capture DNA
oligonucleotide sequences and the noncognatic
via a streptavidin–biotin bridge which can also
sequence showed no significant differences to the
hybridize to HAV DNA targets. Then we measured
blank control sample. The results indicated that
separated
from
we
developed
HAV
DNA
solutions
by
a
targets
Au-Ag
HAV DNA targets could be detected even in the
nano-mushrooms. As shown in Figure 1c, a large
presence of interfering DNA sequences present
number of 100nm nano-mushrooms were coupled
with a more than 103-fold greater concentration in
with MMPs due to DNA hybridization in the
the sample.
the
SERS
intensity
of
separated
presence of the DNA target, while SERS intensity
Scheme 1. a) Schematic illustration of synthesis of mushroom-like Au-Ag SERS probes in two different ways. (1) Fluorescence Raman reports are labeled on the probe DNA, (2) Thiol-containing Raman reports are adsorbed on the AuNPs. b) Multiplex analytical strategy for virus gene DNA/RNA. Three types of SERS nanoprobes were prepared via the functionalization of probe DNA on Au-Ag mushrooms encoded by Raman reports. Each type of DNA/RNA target was captured by the corresponding capture DNA/RNA followed by hybridization with its own SERS nanoprobes, leading to the formation of concomitant multiple sandwich complexes.
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Analytical Chemistry
Multicolor nano-mushrooms
is assembling Raman molecular-labeled alkanethiol
Compared with fluorescent tags which often suffer
DNA on gold nanoparticles. The other is that
from spectral overlap of different fluorophores and
thiol-containing Raman reporters and DNA are
needing excitation light with different wavelength,
co-assembled on the surface of AuNPs. As a
SERS nanoprobes can produce molecular specific
demonstration, we selected ROX-labeled DNA,
vibrational spectra that can easily differentiate
CY3-labeled DNA, 4- Aminothiophenol (ABT)
between mixtures of Raman labels with single-laser
and 4-Nitrothiophenol (NBT) as Raman reporters
excitation. However, we had difficulties with
to obtain four kinds of nano-mushrooms according
obtaining multicolor nano-mushrooms based on the
to the two strategies. Figure S2 presents the SERS
above-mentioned protocol because quite few
spectra of all of the Au-Ag nano-mushrooms and
Raman dyes can be labeled to oligonucleotides and
demonstrates that every specific SERS mushrooms
there are fewer Raman-labeled DNA commercially
can be clearly identified based on its unique
available. Taking advantage of thiol-containing
spectroscopic fingerprint, which is suitable for
Raman reporters, we designed a new protocol to
multiplex biodetection. Predictably, combining the
synthesize SERS-active Au-Ag nano-mushrooms.
Raman-labeling model and the co-assembling
Thus, we had developed two strategies to obtain
model, much more Au-Ag nano-mushrooms can be
Au-Ag
designed and synthesized, having their own SERS
nano-mushrooms
containing
different
spectroscopic fingerprints.
Raman reporters, acting as multicolor SERS-active nanoprobes. As shown in scheme 1(a), one strategy
Figure 3. a) Concentration dependent SERS spectra at different Raman peaks (1590 cm-1 for HIV, 1504 cm-1 for HAV, 1338 cm-1 for HBV ) for HIV, HAV, and HBV DNA detection. The DNA target concentration ranged from 1pM to 10 nM. b) Plot of SERS intensity at selected Raman peaks (1590 cm-1 for HIV) at a function of HIV DNA concentration. c) Plot of SERS intensity at selected Raman peaks (1504cm-1 for HAV) at a function of HAV DNA concentration. d) Plot of SERS intensity at different Raman peaks (1338cm-1 for HBV) at a function of HBV DNA concentration. Error bars indicate the standard deviations from at least 3 measurements (Intensities shown were after background subtraction). 7
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Multiplex SERS detection of DNA
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targets varied from 1pM to 10nM, and the SERS
Having established that Au-Ag nano-mushrooms
spectra changed with the increasing concentration
have
specific
of the three DNA targets (see Figure 3a). It is
hybridization properties and that multicolor Au-Ag
obvious that each SERS spectrum only displays the
nano-mushrooms can be synthesized via different
unique
strategies, we employed them as ready-to-use
corresponding Au-Ag nano-mushroom, and the
SERS nanoprobes for multiplex DNA detection.
specific DNA target can be easily and distinctly
Here, three kinds of Au-Ag nano-mushrooms
identified
fingerprinted with NBT, ROX and ABT were
fingerprint of the nanoprobes. With the decreasing
designed to recognize and hybridize to HAV DNA,
concentration of DNA targets, the SERS peaks
hepatitis
human
from 1338cm-1, 1504cm-1 and 1590cm-1 decreased
immunodeficiency virus (HIV) DNA, respectively.
gradually and blank control sample displayed very
As shown in scheme1 (b), common MMPs
weak SERS signal. As shown in the Figure 3(b-d),
functionalized by three capture DNAs were used to
the SERS signal could be observed as low as 1pM
separate all hybridized Au-Ag nano-mushrooms for
for each of the DNA target, demonstrating the
SERS
multiplexing
strong
B
SERS
signals
virus (HBV)
measurements.
and
DNA
We
and
challenged
the
spectroscopic
according
to
signature
the
capability
of
visually
of
the
the
unique
Au-Ag
nano-mushrooms.
simultaneous detection of three DNA targets in the same sample. The concentration of the DNA
Figure 4. a) Dose–response SERS spectra for miRNA-21 detection. b) Plot of SERS intensity at peak 1504 cm-1 as a function of logarithm of miRNA-21 concentration. The concentration of miRNA-21 ranged from 10fM to 100pM. Error bars indicate the standard deviations from 3 measurements. c) SERS spectra of specific analysis for random RNA. d) SERS intensity from random RNA and blank sample. Error bars indicate the standard deviations from at least 3 measurements (Intensities shown were after background subtraction).
Multiplex SERS detection of microRNA
and
hybridize
microRNA
(miRNA),
Au-Ag
nano-mushrooms can also have the potential for
As the probe DNA can be designed to recognize
multiplex detection of miRNA. For a quantitative 8
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Analytical Chemistry
investigation,
we
Au-Ag
1µM random RNA and the blank sample,
nano-mushroom SERS probes with a series of
indicating that the Au-Ag nano-mushroom probe
concentrations of the synthetic miRNA-21 in a
could recognize and hybridize with the RNA target
range from 10 fM to100 pM. As shown in Figure 4
very specifically. Subsequently, we challenged the
(a, b), the characteristic SERS peak of ROX
Au-Ag nano-mushroom probes for multiplex
(1504cm-1) increased monotonically with the
miRNA
logarithm concentration of miRNA-21, which is
nano-mushroom SERS probes were designed via
similar to the DNA detection. In the absence of
the modification of three types of probe DNA on
miRNA-21, there was no significant SERS signal
Au-Ag nano-mushrooms encoded by ROX, 4-ABT
observed,
control
and CY3, while capture DNA for the three targets
experiment indicated no binding of the Au-Ag
were co-assembled on the MMPs. Each type of
nano-mushroom
lowest
miRNA target was captured by the corresponding
concentration of miRNA-21 target detected was 10
capture DNA followed by hybridization with its
fM (see Figure S3 of Supporting Information for
own SERS probes, leading to the formation of
details). The reason may be that the hybridization
concomitant multiple sandwich complexes. Thus,
which
challenged
means to
the
the
blank
MMPs.
The
between DNA and RNA is more stable. investigated
the
specificity
of
49
the
detection.
Three
types
of
Au-Ag
three miRNA targets in a single sample would be
We also
detected simultaneously.
Au-Ag
Then we investigated
nano-mushroom probes which was used for
the sensitivity of the multiplex RNA assay. As
miRNA detection. Significantly, it can effectively
shown in Figure 5a, in a serial dilution of the
differentiate miRNA-21 from random RNA at pM
samples,
level (Figure 4c.d). Fully complementary 100 pM
miRNA-31 and miRNA-141 from 1 pM to 10 nM
the
concentrations
of
miRNA-21,
miRNA target could be clearly differentiated from
Figure 5. a) Concentration dependent SERS spectra at different Raman peaks (1504 cm-1 for miRNA-21, 1078 cm-1 for miRNA-31, 1590cm-1 for miRNA-141) for miRNA detection. The miRNA target concentration ranged from 1pM to 10 nM. b) Plot of SERS intensity at selected Raman peak (1504 cm-1 for miRNA-21) at a function of miRNA-21 concentration. c) Plot of SERS intensity at selected Raman peak (1078 cm-1 for miRNA-31) at a function of miRNA-31 concentration. d) Plot of SERS intensity at different Raman peak 9
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(1590cm-1 for miRNA-141) at a function of miRNA-141 concentration. Error bars indicate the standard deviations from at least 3 measurements (Intensities shown were after background subtraction).
were detected. The signal intensity of the
SERS detection of serum samples
characteristic SERS peaks of ROX, 4-ABT and CY3 increased with increasing concentration of the
To test the feasibility of the practical application of
miRNA-21, miRNA-31 and miRNA-141 targets.
the Au-Ag nano-mushroom probes, we conducted
As low as 1pM miRNA target could be clearly
analyses of miRNA-21 in biological fluids. As
distinguished
The
demonstrated in Figure 6, we found that there was
quantitative results for the detection of miRNA-21,
no significantly difference between SERS signal
miRNA-31 and miRNA-141 were shown in Figure
from buffer and diluted serum (20%) sample, thus
5(b–d). Also, the multiplex assay for these
the
miRNAs exhibited a good dynamic range of 5
anti-interference ability. Combined with the result
orders.
As the ready-to-use nano-mushrooms can
that the Au-Ag nano-mushroom SERS probe could
be easily synthesized, and two strategies have been
specifically recognize the RNA target in the
developed to obtain Au-Ag nano-mushrooms
presence of 104 fold of the random RNA in the
containing various Raman reporters, the probe
buffer (Figure 4d). This clearly demonstrated that
DNA can also be designed to recognize and
our SERS probes could selectively identify RNA
hybridize other kinds of bioactive molecules
target even in serum. Since serum is the most
through assembling the aptamer sequence on
complicated biological fluid in in-vitro diagnostics,
AuNPs, thus the Au-Ag nano-mushroom probes
other body fluidics are relatively clean mediums
have the great potential for multiplex detection of
and contain few interfering proteins. Accordingly,
different biomarkers and the mixture of various
the Au-Ag nano-mushroom probes could also be
bioactive molecules, including cell, protein and
used in other body fluidics such as saliva, urine and
small
from
the
molecules.24,50-51,
blank
control.
Therefore,
Au-Ag
nano-mushroom
had
strong
ascites, which may greatly broaden the application
Au-Ag bio-
range of the SERS probes, and facilitate the
functionalization could be developed to be a
molecular diagnosis of diseases in an early stage
universal multi-analysis platform. 24, 52
which is necessary for effective treatment.44
nano-mushroom
probe
without
further
CONCLUSION In summary, we developed multicolor Au-Ag nano-mushrooms that can act as ready-to-use SERS nanoprobes
for
ultrasensitive
and
multiplex
DNA/RNA detection. We demonstrated that the Au-Ag nano-mushroom probes have specific hybridization properties because of the inherent ability of DNA/RNA hybridization with exposed oligonucleotides on AuNPs. Multicolor Au-Ag nano-mushrooms
become
available
via
two
strategies for the assembly of Raman reporters, enabling them to recognize and distinguish specific
Figure 6. Detection of 100 pM miRNA-21 target in
DNA/RNA
buffer and in diluted (20%) serum. Data were
compared
collected from at least three independent sets of experiments.
Intensities
shown
were
targets with
from other
others.
Especially,
silver-containing
nanostructures, the Au-Ag mushroom SERS probes
after
are easy to synthesize and
background subtraction.
could be used without
further bio-functionalization. Therefore, Au-Ag 10
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Analytical Chemistry
nano-mushrooms
hold
great
promise
for
(3) Wang, Y.; Yan, B.; Chen, L. Chem. Rev. 2012, 113,
developing multiplex bio-sensing strategies for
1391-1428.
molecular
(4) Zhang, P.; Zhang, R.; Gao, M.; Zhang, X. ACS Appl.
diagnostics
and
cellular
imaging.
Because of their bimetallic and nanobio-based
Mater. Interfaces.2013, 6, 370-376.
properties, these Au-Ag nano-mushrooms also hold
(5) Song, C.; Yang, Y.; Yang, B.; Sun, Y.; Zhao, Y.; Wang,
great potential for other applications in chemistry
L. Nanoscale. 2016, 8, 17365-17373.
and life science.
(6) Saha, K.; Agasti, S. S.; Kim, C.; Li, X.; Rotello, V. M. Chem. Rev. 2012, 112, 2739-2779. (7) Lei, J.; Ju, H. Chem. Soc. Rev. 2012, 41, 2122-2134.
ASSOCIATED CONTENT
(8) Baker, B. R.; Lai, R. Y.; Wood, M. S.; Doctor, E. H.;
Supporting Information
Heeger, A. J.; Plaxco, K. W. J. Am. Chem. Soc. 2006, 128,
Figure
S1
showed
time-dependent
the
Raman
UV-vis
results
of
spectra the
3138-3139.
and
(9) Anker, J. N.; Hall, W. P.; Lyandres, O.; Shah, N. C.;
Au-Ag
Zhao, J.; Van Duyne, R. P. Nat. Mater. 2008, 7, 442-453.
nano-mushrooms. Figure S2 showed multi-color
(10) Alvarez-Puebla, R. A.; Liz-Marzan, L. M. Chem. Soc.
Au-Ag nano-mushrooms. FigureS3 showed the the
Rev. 2012, 41, 43-51.
LOD of miRNA-141 assay. Table S1 showed blank
(11) Driskell, J. D.; Tripp, R. A. Chem. Commun. 2010, 46,
SERS signals in the detection of DNA and miRNA
3298-3300.
targets. TableS2 showed the sequences of the DNA
(12) Alvarez‐Puebla, R. A.; Liz‐Marzán, L. M. Angew.
and miRNA used in the paper.
Chem., Int. Ed. 2012, 51, 11214-11223.
The Supporting Information is available free of charge
(13) Cho, W. J.; Kim, Y.; Kim, J. K. ACS Nano. 2011, 6,
on the ACS Publications website.
249-255.
AUTHOR INFORMATION
(14) Chung, A. J.; Huh, Y. S.; Erickson, D. Nanoscale. 2011, 3, 2903-2908.
Corresponding Author
(15) Li, W.; Camargo, P. H. C.; Lu, X.; Xia, Y. Nano Lett.
*E-mail:
[email protected] (S.S.). 2009, 9, 485-490.
[email protected] (S.M.) (16) Qian, X.-M.; Nie, S. Chem. Soc. Rev. 2008, 37,
Author Contributions
912-920.
‖J.S. and D.W. contributed equally.
(17) Fang, Y.; Seong, N.-H.; Dlott, D. D. Science. 2008, 321,
Notes
388-392.
The authors declare no competing financial interest.
(18) Hwang, J. H.; Singhal, N. K.; Lim, D. K.; Nam, J. M. Bull. Korean Chem. Soc. 2015, 36, 882-886.
ACKNOWLEDGMENT
(19) Oh, J.-W.; Lim, D.-K.; Kim, G.-H.; Suh, Y. D.; Nam,
We thank the National Basic Research Program of
J.M. J. Am. Chem. Soc. 2014, 136, 14052-14059.
China (2013CB932800 and 2016YFA02012), the
(20) Kang, J. W.; So, P. T.; Dasari, R. R.; Lim, D.-K. Nano
National Science Foundation of China (21373260,
Lett.2015, 15, 1766-1772.
31571014 and 21390414), Chinese Academy of
(21) Song, J.; Duan, B.; Wang, C.; Zhou, J.; Pu, L.; Fang, Z.;
Sciences (QYZDJ-SSW-SLH031) and Alexander von
Wang, P.; Lim, T. T.; Duan, H. J. Am. Chem. Soc. 2014, 136,
Humboldt Foundation for the financial support.
6838-6841. (22) Osberg, K. D.; Rycenga, M.; Harris, N.; Schmucker, A.
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