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Nature Methods
Supplement issue: April 2011
Volume 8, No 4
Summary of the
supplement on single-cell analysis
Read the supplement at http://www.nature.com/nmeth/journal/v8/n4s/index.html
Foreword
In a series
of commissioned pieces, authors discuss methods for the analysis of
single cells and consider technical developments still needed. Three
Reviews describe methods to study single-cell gene expression, peptide,
and small-molecule metabolite profiles. Two Perspectives describe
live-cell imaging and clonal analysis applied to single stem cells. A
Commentary provides an overview of the technological developments
underlying single-cell analysis and discusses applications of genome
analysis in single cells.
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Single-cell
analysis - Methods to study single cell genomics
Since the
beginning of research on cell biology, say Stephen Quake and Tomer Kalisky in a
Commentary, technological advances have driven biological understanding
of the single cell. Early microscopes that permitted biologists to
observe single cells have led, via molecular marking techniques and
flow cytometry, to the ability to rapidly monitor dozens of markers on
thousands of individual cells. But the scale of single-cell analysis
has not stopped there. The authors discuss methodologies, such as
microfluidics, that are enabling highly parallel genome-scale analysis
at single-cell resolution. They consider new applications—including
haplotyping of human cells and the analysis of complex bacterial
populations—for whole-genome sequencing of single cells. (Nat. Methods
8, 311–314, 2011)
Transcriptomes - Methods for single-cell
transcriptome profiling
Strategies for single-cell
transcriptome analysis
Cells, even when
derived from a common tissue source or progenitor, vary in their gene
expression, and this in turn influences their behavior and fate. It is
thus important to analyze transcriptomes at single-cell resolution. In
a Review, Azim Surani and colleagues
take the reader through the steps of single-cell transcriptome
analysis, from the isolation of single cells to the release and reverse
transcription of mRNA and the amplification of the resulting cDNA,
followed by DNA microarray analysis or high-throughput sequencing. The
authors present available software tools for bioinformatic analysis of
sequence data and discuss current limitations of single-cell
transcriptome analyses such as the lack of discrimination between sense
and antisense strands and the exclusion of non-polyadenylated
transcripts. Finally, they describe up-and-coming areas such as
single-molecule sequencing for full-length RNAs and the ability to
sequence RNA that is actively being translated. (Nat. Methods 8,
S6–S11, 2011)
Transcript imaging - Validating transcripts
in single cells
Schematic of a branched
probe for transcript imaging
High-throughput
sequencing of transcripts in a single cell yields bulk information on
what is being transcribed; to follow up on single transcripts in more
detail, one needs to visualize the transcripts. In a Review, Alexander
van Oudenaarden and Shalev Itzkovitz discuss methods for
single-molecule transcript imaging in living and fixed cells. For
transcript imaging in fixed cells, they describe fluorescence in situ
hybridization (FISH) and derivative approaches based on labeled probes.
For live cells, the authors compare methods based on gene fusion to the
MS2 bacteriophage coat protein and molecular beacons. They discuss
imaging technology and data analysis needed to extract information from
single-molecule FISH experiments. In an outlook section they provide a
glimpse into what is still required to make these methods more
sensitive and to combine them with quantitative measurements of DNA and
protein for a more complete picture of the expression networks that
underlie tissue function. (Nat. Methods 8, S12–S19, 2011)
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Relevance of
circulating tumor cells, extracellular nucleic acids, and exosomes in
breast cancer.
Friel AM, Corcoran C, Crown J, O'Driscoll L.
Breast Cancer Res Treat. 2010 Oct;123(3): 613-625
School of Pharmacy and Pharmaceutical Sciences &
Molecular Therapeutics for Cancer Ireland, Trinity College Dublin,
Dublin 2, Ireland.
Early detection of
cancer is vital to improved overall survival rates. At present,
evidence is accumulating for the clinical value of detecting occult
tumor cells in peripheral blood, plasma, and serum specimens from
cancer patients. Both molecular and cellular approaches, which differ
in sensitivity and specificity, have been used for such means.
Circulating tumor cells and extracellular nucleic acids have been
detected within blood, plasma, and sera of cancer patients. As the
presence of malignant tumors are clinically determined and/or confirmed
upon biopsy procurement-which in itself may have detrimental effects in
terms of stimulating cancer progression/metastases-minimally invasive
methods would be highly advantageous to the diagnosis and prognosis of
breast cancer and the subsequent tailoring of targeted treatments for
individuals, if reliable panels of biomarkers suitable for such an
approach exist. Herein, we review the current advances made in the
detection of such circulating tumor cells and nucleic acids, with
particular emphasis on extracellular nucleic acids, specifically
extracellular mRNAs and discuss their clinical relevance.
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Visualizing high
error levels during gene expression in living bacterial cells.
Meyerovich M, Mamou G, Ben-Yehuda S.
Proc Natl Acad Sci U S A. 2010 Jun 22;107(25):
11543-11548
Department of Microbiology and Molecular Genetics,
Institute for Medical Research, Israel-Canada, Hebrew
University-Hadassah Medical School, Hebrew University of Jerusalem,
91120 Jerusalem, Israel.
To monitor
inaccuracy in gene expression in living cells, we designed an
experimental system in the bacterium Bacillus subtilis whereby
spontaneous errors can be visualized and quantified at a single-cell
level. Our strategy was to introduce mutations into a chromosomally
encoded gfp allele, such that errors in protein production are reported
in real time by the formation of fluorescent GFP molecules. The data
reveal that the amount of errors can greatly exceed previous estimates,
and that the error rate increases dramatically at lower temperatures
and during stationary phase. Furthermore, we demonstrate that when
facing an antibiotic threat, an increase in error level is sufficient
to allow survival of bacteria carrying a mutated antibiotic-resistance
gene. We propose that bacterial gene expression is error prone,
frequently yielding protein molecules that differ slightly from the
sequence specified by their DNA, thus generating a cellular reservoir
of nonidentical protein molecules. This variation may be a key factor
in increasing bacterial fitness, expanding the capability of an
isogenic population to face environmental challenges.
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A multimarker
QPCR-based platform for the detection of circulating tumour cells in
patients with early-stage breast cancer.
Molloy TJ, Devriese LA, Helgason HH, Bosma AJ,
Hauptmann M, Voest EE, Schellens JH, Van't Veer LJ.
Br J Cancer. 2011 May 17. [Epub ahead of print]
Division of Experimental Therapy, The Netherlands
Cancer Institute, Plesmanlaan 121, 1066 CX Amsterdam, The Netherlands.
Background: The
detection of circulating tumour cells (CTCs) has been linked with poor
prognosis in advanced breast cancer. Relatively few studies have been
undertaken to study the clinical relevance of CTCs in early-stage
breast cancer.Methods:In a prospective study, we evaluated CTCs in the
peripheral blood of 82 early-stage breast cancer patients. Control
groups consisted of 16 advanced breast cancer patients and 45 healthy
volunteers. The CTC detection was performed using ErbB2/EpCAM
immunomagnetic tumour cell enrichment followed by multimarker
quantitative PCR (QPCR). The CTC status and common clinicopathological
factors were correlated to relapse-free, breast cancer-related and
overall survival.
Results: Circulating tumour cells were detected in
16 of 82 (20%) patients with early-stage breast cancer and in 13 out of
16 (81%) with advanced breast cancer. The specificity was 100%. The
median follow-up time was 51 months (range: 17-60). The CTC positivity
in early-stage breast cancer patients resulted in significantly poorer
relapse-free survival (log rank test: P=0.003) and was an independent
predictor of relapse-free survival (multivariate hazard ratio=5.13,
P=0.006, 95% CI: 1.62-16.31).
Conclusion: The detection of CTCs in peripheral
blood of early-stage breast cancer patients provided prognostic
information for relapse-free survival.
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An improved one-tube
RT-PCR protocol for analyzing single-cell gene expression in individual
mammalian cells.
Li Y, Thompson H, Hemphill C, Hong F, Forrester J,
Johnson RH, Zhang W, Meldrum DR.
Anal Bioanal Chem. 2010 Jul;397(5): 1853-1859
Center for Ecogenomics, The Biodesign Institute,
Arizona State University, P.O. Box 876501, Tempe, AZ 85287-6501, USA
It is well known
that gene expression is regulated at the level of individual cells, and
more evidence is now emerging that heterogeneity of cell regulation is
orders of magnitude greater than previously thought. In order to detect
meaningful variations in transcription levels, it is necessary to
measure gene expression at single cell levels rather than in bulk
cells, where individual differences or heterogeneity could be lost. In
this work, we report an improved reverse-transcriptase polymerase chain
reaction (RT-PCR) protocol which allows the direct measurement of gene
expression in one tube (5-25 microl of total PCR mixture) at the single
mammalian cell level. The protocol employs a new cell lysis buffer, and
involves no RNA isolation or nested PCR steps, significantly reducing
the possibility of contamination and errors. We successfully applied
this protocol in qRT-PCR and linear-after-the-exponential (LATE)-PCR to
analyze selected genes of various expression levels from three cell
lines. Although further characterization of RNA stability is important,
the preliminary results showed that gene expression heterogeneity could
be common among members of genetically identical cell populations. The
protocol illustrated can be utilized for a wide array of applications
without much modification, such as cancer cell analysis and
preimplantation genetic diagnostics. In addition, the protocol is based
on intercalator-based (SYBR Green PCR) chemistry, which is less
expensive and suitable for high-throughput platforms.
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Defining
cell populations with single-cell gene expression profiling:
correlations and identification of astrocyte subpopulations.
Stahlberg A, Andersson D, Aurelius J, Faiz M, Pekna
M, Kubista M, Pekny M.
Nucleic Acids Res. 2011 Mar;39(4): e24
Center for Brain Repair and Rehabilitation,
Department of Clinical Neuroscience and Rehabilitation, Institute of
Neuroscience and Physiology, Sahlgrenska Academy at University of
Gothenburg, Medicinaregatan 9A, 413 90 Gothenburg, Sweden
Single-cell gene
expression levels show substantial variations among cells in seemingly
homogenous populations. Astrocytes perform many control and regulatory
functions in the central nervous system. In contrast to neurons, we
have limited knowledge about functional diversity of astrocytes and its
molecular basis. To study astrocyte heterogeneity and stem/progenitor
cell properties of astrocytes, we used single-cell gene expression
profiling in primary mouse astrocytes and dissociated mouse neurosphere
cells. The transcript number variability for astrocytes showed
lognormal features and revealed that cells in primary cultures to a
large extent co-express markers of astrocytes and neural
stem/progenitor cells. We show how subpopulations of cells can be
identified at single-cell level using unsupervised algorithms and that
gene correlations can be used to identify differences in activity of
important transcriptional pathways. We identified two subpopulations of
astrocytes with distinct gene expression profiles. One had an
expression profile very similar to that of neurosphere cells, whereas
the other showed characteristics of activated astrocytes in vivo.
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Single-cell qPCR on
dispersed primary pituitary cells - an optimized protocol.
Hodne K, Haug TM, Weltzien FA.
BMC Mol Biol. 2010 Nov 12;11:82.
Norwegian School of Veterinary Science, Department
of Basic Sciences and Aquatic Medicine, Oslo, Norway.
BACKGROUND: The
incidence of false positives is a potential problem in single-cell PCR
experiments. This paper describes an optimized protocol for single-cell
qPCR measurements in primary pituitary cell cultures following
patch-clamp recordings. Two different cell harvesting methods were
assessed using both the GH₄ prolactin producing cell line from rat, and
primary cell culture from fish pituitaries.
RESULTS:
Harvesting whole cells followed by cell lysis and qPCR performed
satisfactory on the GH₄ cell line. However, harvesting of whole cells
from primary pituitary cultures regularly produced false positives,
probably due to RNA leakage from cells ruptured during the dispersion
of the pituitary cells. To reduce RNA contamination affecting the
results, we optimized the conditions by harvesting only the cytosol
through a patch pipette, subsequent to electrophysiological
experiments. Two important factors proved crucial for reliable
harvesting. First, silanizing the patch pipette glass prevented foreign
extracellular RNA from attaching to charged residues on the glass
surface. Second, substituting the commonly used perforating antibiotic
amphotericin B with β-escin allowed efficient cytosol harvest without
loosing the giga seal. Importantly, the two harvesting protocols
revealed no difference in RNA isolation efficiency.
CONCLUSION:
Depending on the cell type and preparation, validation of the
harvesting technique is extremely important as contaminations may give
false positives. Here we present an optimized protocol allowing secure
harvesting of RNA from single cells in primary pituitary cell culture
following perforated whole cell patch clamp experiments.
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RT-qPCR based
quantitative analysis of gene expression in single bacterial cells.
Gao W, Zhang W, Meldrum DR.
J Microbiol Methods. 2011 Jun;85(3): 221-227
Recent evidence
suggests that cell-to-cell difference at the gene expression level is
an order of magnitude greater than previously thought even for isogenic
bacterial populations. Such gene expression heterogeneity determines
the fate of individual bacterial cells in populations and could also
affect the ultimate fate of populations themselves. To quantify the
heterogeneity and its biological significance, quantitative methods to
measure gene expression in single bacterial cells are needed. In this
work, we developed two SYBR Green-based RT-qPCR methods to determine
gene expression directly in single bacterial cells. The first method
involves a single-tube operation that can analyze one gene from each
bacterial cell. The second method is featured by a two-stage protocol
that consists of RNA isolation from a single bacterial cell and cDNA
synthesis in the first stage, and qPCR in the second stage, which
allows determination of expression level of multiple genes
simultaneously for single bacterial cells of both gram-positive and
negative. We applied the methods to stress-treated (i.e. low pH and
high temperature) Escherichia coli populations. The reproducible
results demonstrated that the method is sensitive enough not only for
measuring cellular responses at the single-cell level, but also for
revealing gene expression heterogeneity among the bacterial cells.
Furthermore, our results showed that the two-stage method can
reproducibly measure multiple highly expressed genes from a single E.
coli cell, which exhibits important foundation for future development
of a high throughput and lab-on-chips whole-genome RT-qPCR methodology
for single bacterial cells.
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Real-time PCR of
single bacterial cells on an array of adhering droplets.
Shi X, Lin LI, Chen SY, Chao SH, Zhang W, Meldrum DR.
Lab Chip. 2011 May 23
Center for Biosignatures Discovery Automation,
Arizona State University, PO Box 876501. Tempe, AZ, USA
Real-time PCR at
the single bacterial cell level is an indispensable
tool to quantitatively reveal the heterogeneity of isogenetic cells.
Conventional PCR platforms that utilize microtiter plates or PCR tubes
have been widely used, but their large reaction volumes are not suited
for sensitive single-cell analysis. Microfluidic devices provide high
density, low volume PCR chambers, but they are usually expensive and
require dedicated equipment to manipulate liquid and perform detection.
To address these limitations, we developed an inexpensive chip-level
device that is compatible with a commercial real-time PCR thermal
cycler to perform quantitative PCR for single bacterial cells. The chip
contains twelve surface-adhering droplets, defined by hydrophilic
patterning, that serve as real-time PCR reaction chambers when they are
immersed in oil. A one-step process that premixed reagents with cell
medium before loading was applied, so no on-chip liquid manipulation
and DNA purification were needed. To validate its application for
genetic analysis, Synechocystis PCC 6803 cells were loaded on the chip
from 1000 cells to one cell per droplet, and their 16S rRNA gene (two
copies per cell) was analyzed on a commercially available ABI StepOne
real-time PCR thermal cycler. The result showed that the device is
capable of genetic analysis at single bacterial cell level with C(q)
standard deviation less than 1.05 cycles. The successful rate of this
chip-based operation is more than 85% at the single bacterial cell
level.
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Paired analysis of
TCRα and TCRβ chains at the single-cell level in mice.
Dash P, McClaren JL, Oguin TH 3rd, Rothwell W, Todd
B, Morris MY, Becksfort J, Reynolds C, Brown SA, Doherty PC, Thomas PG.
J Clin Invest. 2011 Jan 4;121(1): 288-295
St Jude Children’s Research Hospital, Memphis,
Tennessee 38105-3678, USA.
Characterizing the
TCRα and TCRβ chains expressed by T cells responding to a given
pathogen or underlying autoimmunity helps in the development of
vaccines and immunotherapies, respectively. However, our understanding
of complementary TCRα and TCRβ chain utilization is very limited for
pathogen- and autoantigen-induced immunity. To address this problem, we
have developed a multiplex nested RT-PCR method for the simultaneous
amplification of transcripts encoding the TCRα and TCRβ chains from
single cells. This multiplex method circumvented the lack of antibodies
specific for variable regions of mouse TCRα chains and the need for
prior knowledge of variable region usage in the TCRβ chain, resulting
in a comprehensive, unbiased TCR repertoire analysis with paired
coexpression of TCRα and TCRβ chains with single-cell resolution. Using
CD8+ CTLs specific for an influenza epitope recovered directly from the
pneumonic lungs of mice, this technique determined that 25% of such
effectors expressed a dominant, nonproductively rearranged Tcra
transcript. T cells with these out-of-frame Tcra mRNAs also expressed
an alternate, in-frame Tcra, whereas approximately 10% of T cells had 2
productive Tcra transcripts. The proportion of cells with biallelic
transcription increased over the course of a response, a finding that
has implications for immune memory and autoimmunity. This technique may
have broad applications in mouse models of human disease.
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Single Cell RT-PCR
on Mouse Embryos: A General Approach for Developmental Biology
Wolfgang Mann and Thomas Haaf
Nicola King (ed.), RT-PCR Protocols: Second Edition,
Methods in Molecular Biology, vol. 630
Springer Science
Preimplantation
development is a complicated process, which involves many genes. We
have investigated the expression patterns of 17 developmentally
important genes and isoforms in early mouse embryos as well as in
single cells of the mouse embryo. The comparison is an excellent
example for showing the importance of studying heterogeneity among cell
populations on the RNA level, which is being increasingly addressed in
basic research and medical sciences, particularly with a link to
diagnostics (e.g. the analysis of circulating tumor cells and their
progenitors). The ubiquitously expressed histone variant H3f3a and the
transcription factor Pou5f1 generated mRNA-derived products in all
analyzed preimplantation embryos (up to the morula stage) and in all
analyzed blastomeres from 16-cell embryos, indicating a rather uniform
reactivation of pluripotency gene expression during mouse
preimplantation development. In contrast, genes that have been
implicated in epigenetic genome reprogramming, such as DNA
methyltransferases, methylcytosine-binding proteins, or base excision
repair genes revealed considerable variation between individual cells
from the same embryo and even higher variability between cells from
different embryos. We conclude that at a given point of time, the
transcriptome encoding the reprogramming machinery and, by
extrapolation, genome reprogramming differs between blastomeres. It is
tempting to speculate that cells expressing the reprogramming machinery
have a higher developmental potential.
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High throughput
single cell expression profiling: Taking a closer look on biological
response
Mikael Kubista, Linda Strömbom, David Svec,
Vendula Rusnakova & Anders Stahlberg
TATAA Biocenter, Gothenburg, Sweden and the
Institute of Biotechnology, CAS
European Pharmaceutical Review, Volume 16, Issue 2,
2011
Molecular analysis
of tissue and in most cases also of bodily fluids is complicated
because of tissue heterogeneity and the presence of many different cell
types. Even cells of apparently the same type show substantial
variation in gene expression under virtually identical conditions. When
analysing classical samples based on tens of thousands of cells, this
natural variability among cells is lost. With the advent of real-time
quantitative polymerase chain reaction (qPCR), we have a most powerful
tool to study diversity on the single cell level and can detect rare
cells that are critical to treatment or survival.
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Why Single Cells
Matter
Fluidigm Corporation
A Whole New World: Expression Profi
ling of Single Cells
- Who Wants to be
Average? versus Actual Averaged
Within a population of seemingly identical cells, it
is possible that
variations in gene expression differ dramatically on a cell-to-cell
level. These differences will be masked by the averaging effect of
studying pooled samples. The solution is to examine multiple individual
cells to identify those bearing unique transcriptomes. “There are very few people who pay
attention to the advantages and importance of studying single cells,” said
Ron McKay, Chief of the Laboratory of Molecular Biology at the National
Institute of Neurological Disorders and Stroke in Bethesda, Maryland,
in an article entitled A closer look at the single cell, Nature Reports
stem cells, May 7, 2009. “They talk
as if they do. They use a FACS machine and act as if they have
single-cell data. But they don’t. They have data on a population, and
that’s a completely different thing.”
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Detection and
quantification of mRNA in single human polar bodies: a minimally
invasive test of gene expression during oogenesis.
Klatsky PC, Wessel GM, Carson SA.
Mol Hum Reprod. 2010 Dec;16(12): 938-943
Division of Reproductive Endocrinology and
Infertility, Women and Infants Hospital, Alpert School of Medicine,
Brown University, 101 Dudley Street, Providence, RI 02905, USA
Proteins and mRNA
produced in oogenesis support embryonic development until the zygotic
transition, 3 days after fertilization. Since polar bodies can be
biopsied with little if any harm to the oocyte, we tested the
hypothesis that mRNA originating from expression in the meiotic oocyte
is present and detectable in a single polar body prior to insemination.
Human oocytes were obtained from patients undergoing controlled ovarian
hyperstimulation and intracytoplasmic sperm injection. Immature oocytes
were cultured overnight and inspected the following day for maturation.
Metaphase II oocytes underwent polar body biopsy followed by reverse
transcription without RNA isolation. Sibling oocytes were similarly
prepared. Complementary DNA from all samples were pre-amplified over 15
cycles for candidate genes using selective primers. Real-time PCR was
performed to detect and quantify relative single-cell gene expression.
Polar body mRNA was detected in 11 of 12 candidate genes. Transcripts
that were present in greater abundance in the oocyte were more likely
to be detected in qPCR replicates from single polar bodies.
Pre-amplification of cDNA synthesized without RNA isolation can
facilitate the quantitative detection of mRNA in single human polar
bodies.
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Modelling and
measuring single cell RNA expression levels find considerable
transcriptional differences among phenotypically identical cells.
Subkhankulova T, Gilchrist MJ, Livesey FJ.
BMC Genomics. 2008 Jun 3;9: 268.
Gurdon Institute and Department of Biochemistry,
University of Cambridge, Tennis Court Road, Cambridge, CB2 1 QN, UK
BACKGROUND:
Phenotypically identical cells demonstrate predictable, robust
behaviours. However, there is uncertainty as to whether phenotypically
identical cells are equally similar at the underlying transcriptional
level or if cellular systems are inherently noisy. To answer this
question, it is essential to distinguish between technical noise and
true variation in transcript levels. A critical issue is the
contribution of sampling effects, introduced by the requirement to
globally amplify the single cell mRNA population, to observed
measurements of relative transcript abundance.
RESULTS: We used
single cell microarray data to develop simple mathematical models, ran
Monte Carlo simulations of the impact of technical and sampling effects
on single cell expression data, and compared these with experimental
microarray data generated from single embryonic neural stem cells in
vivo. We show that the actual distribution of measured gene expression
ratios for pairs of neural stem cells is much broader than that
predicted from our sampling effect model.
CONCLUSION: Our
results confirm that significant differences in gene expression levels
exist between phenotypically identical cells in vivo, and that these
differences exceed any noise contribution from global mRNA
amplification.
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Single-cell
NF-kappaB dynamics reveal digital activation and analogue information
processing.
Tay S, Hughey JJ, Lee TK, Lipniacki T, Quake SR,
Covert MW.
Nature. 2010 Jul 8;466(7303): 267-271
Department of Bioengineering, Stanford University,
Stanford, California 94305, USA
Cells operate in
dynamic environments using extraordinary communication capabilities
that emerge from the interactions of genetic circuitry. The mammalian
immune response is a striking example of the coordination of different
cell types. Cell-to-cell communication is primarily mediated by
signalling molecules that form spatiotemporal concentration gradients,
requiring cells to respond to a wide range of signal intensities. Here
we use high-throughput microfluidic cell culture and fluorescence
microscopy, quantitative gene expression analysis and mathematical
modelling to investigate how single mammalian cells respond to
different concentrations of the signalling molecule tumour-necrosis
factor (TNF)-alpha, and relay information to the gene expression
programs by means of the transcription factor nuclear factor
(NF)-kappaB. We measured NF-kappaB activity in thousands of live cells
under TNF-alpha doses covering four orders of magnitude. We find, in
contrast to population-level studies with bulk assays, that the
activation is heterogeneous and is a digital process at the single-cell
level with fewer cells responding at lower doses. Cells also encode a
subtle set of analogue parameters to modulate the outcome; these
parameters include NF-kappaB peak intensity, response time and number
of oscillations. We developed a stochastic mathematical model that
reproduces both the digital and analogue dynamics as well as most gene
expression profiles at all measured conditions, constituting a broadly
applicable model for TNF-alpha-induced NF-kappaB signalling in various
types of cells. These results highlight the value of high-throughput
quantitative measurements with single-cell resolution in understanding
how biological systems operate.
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Single-allele
analysis of transcription kinetics in living mammalian cells.
Yunger S, Rosenfeld L, Garini Y, Shav-Tal Y.
Nat Methods. 2010 Aug;7(8): 631-633
The Mina and Everard Goodman Faculty of Life
Sciences and Institute of Nanotechnology, Bar-Ilan University, Ramat
Gan, Israel.
We generated a system for in vivo visualization and
analysis of mammalian mRNA transcriptional kinetics of single alleles
in real time, using single-gene integrations. We obtained
high-resolution transcription measurements of a single cyclin D1 allele
under endogenous or viral promoter control, including quantification of
temporal kinetics of transcriptional bursting, promoter firing, nascent
mRNA numbers and transcription rates during the cell cycle, and in
relation to DNA replication.
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Acoustic
microstreaming increases the efficiency of reverse transcription
reactions comprising single-cell quantities of RNA.
Boon WC, Petkovic-Duran K, White K, Tucker E,
Albiston A, Manasseh R, Horne MK, Aumann TD.
Biotechniques. 2011 Feb;50(2):116-169
Florey Neuroscience Institutes, The University of
Melbourne, Parkville, Victoria, Australia; Centre of Neuroscience, The
University of Melbourne, Parkville, Victoria, Australia
Correlating gene
expression with behavior at the single-cell level is difficult, largely
because the small amount of available mRNA (<1 pg) degrades before
it can be reverse transcribed into a more stable cDNA copy. This study
tested the capacity for a novel acoustic microstreaming method
("micromixing"), which stirs fluid at microliter scales, to improve
cDNA yields from reverse transcription (RT) reactions comprising
single-cell quantities of RNA. Micromixing significantly decreased the
number of qPCR cycles to detect cDNA representing mRNA for hypoxanthine
phosphoribosyl-transferase (Hprt) and nuclear receptor-related 1
(Nurr1) by ~9 and ~15 cycles, respectively. The improvement was
equivalent to performing RT with 10- to 100-fold more cDNA in the
absence of micromixing. Micromixing enabled reliable detection of the
otherwise undetectable, low-abundance transcript, Nurr1. It was most
effective when RNA concentrations were low (0.1-1 pg/µL, a
"single-cell equivalent") but had lesser effects at higher RNA
concentrations (~1 ng/µL). This was supported by imaging
experiments showing that micromixing improved mixing of a low
concentration (20 pg/µL) of fluorescence-labeled RNA but not a
higher concentration (1 ng/µL). We conclude that micromixing
significantly increases RT yields obtainable from single-cell
quantities of RNA.
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Quantitative
single-cell gene expression measurements of multiple genes in response
to hypoxia treatment
Jia Zeng, Jiangxin Wang, Weimin Gao, Aida
Mohammadreza, Laimonas Kelbauskas, Weiwen Zhang, Roger H. Johnson and
Deirdre R. Meldrum
Anal Bioanal Chem 2011
Cell-to-cell
heterogeneity in gene transcription plays a central role in a variety
of vital cell processes. To quantify gene expression heterogeneity
patterns among cells and to determine their biological significance,
methods to measure gene expression levels at the single-cell level are
highly needed. We report an experimental technique based on the
DNA-intercalating fluorescent dye SYBR green for quantitative
expression level analysis of up to ten selected genes in single
mammalian cells. The method features a two-step procedure consisting of
a step to isolate RNA from a single mammalian cell, synthesize cDNA
from it, and a qPCR step. We applied the method to cell populations
exposed to hypoxia, quantifying expression levels of seven different
genes spanning a wide dynamic range of expression in randomly picked
single cells. In the experiment, 72 single Barrett’s esophageal
epithelial (CP-A) cells, 36 grown under normal physiological conditions
(controls) and 36 exposed to hypoxia for 30 min, were randomly
collected and used for measuring the expression levels of 28S rRNA,
PRKAA1, GAPDH, Angptl4, MT3, PTGES, and VEGFA genes. The results
demonstrate that the method is sensitive enough to measure alterations
in gene expression at the single-cell level, clearly showing
heterogeneity within a cell population. We present technical details of
the method development and implementation, and experimental results
obtained by use of the procedure. We expect the advantages of this
technique will facilitate further developments and advances in the
field of single-cell gene expression profiling on a nanotechnological
scale, and eventually as a tool for future point-of-care medical
applications.
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