SCIENCE
GRAPHIC: KELLIE HOLOSKI/
SCIENCE
By Ning Ma and Stefanie S. Jeffrey
C
ancer is associated with consider-
able morbidity and mortality, and
despite therapeutic advances, it still
represents the second leading cause
of death worldwide ( 1 ). As cancers
grow, evolve, and spread, they shed
circulating tumor cells (CTCs), as well as
other tumor-associated cells and products,
into the bloodstream. Capturing and ana-
lyzing CTCs or other tumor-associated cells
and products from a patient’s blood sample
can provide insight into a particular can-
cer’s biology, response to treatment, and/
or potential therapeutic targets ( 2 ). CTCs
are heterogeneous; a pressing question con-
cerns which CTCs represent those directly
involved in metastasis, the major cause of
cancer-related death. On page 1468 of this
issue, Ebright et al. ( 3 ) identify genes in
patient-derived CTCs encoding ribosomal
proteins (RPs) that were associated with
metastatic progression in mouse models,
poor outcome in patients, and alterations
in global translation. These findings could
point to potential biomarkers or targets for
future metastatic cancer therapies.
Tumors and their metastases are spatially
and temporally heterogeneous, highly influ-
enced by the context of the microenviron-
ment in which they grow and their expo-
sure to immune cells, stromal cells, and cell
products ( 4 ). As tumors evolve according to
their intrinsic biology, their environment,
and drug selection pressures, genetic, epi-
genetic, and transcriptional alterations can
diverge ( 5 ). Moreover, biomarker and thera-
peutic target discordance may occur be-
tween the primary tumor and metastases,
and even between different metastases, in
the same patient. This makes optimal treat-
ment selection a challenge throughout the
course of disease.
Because metastases are commonly mul-
tifocal, it is impractical, invasive, and po-
tentially dangerous to biopsy each one to
identify changing biomarkers that may in-
fluence subsequent drug selection. Instead,
sampling blood or other bodily fluids such
as urine, saliva, or tears—known as “liquid
biopsy”—facilitates the analyses of cells or
tumor-associated products that may offer
a more comprehensive snapshot of tumor
burden and its molecular diversity through-
out the body at any given time. Liquid bi-
opsy components under investigation in-
clude CTCs, either separate or aggregated
with immune cells; circulating endothelial,
stem, and stromal cells; cell-free compo-
nents such as DNA and RNAs; and nu-
merous other factors, such as extracellular
vesicles (see the figure). Currently approved
clinical use of liquid biopsy is limited but
expanding, with a few approved tests for
cancer screening or for identification of
specific actionable mutations that guide
cancer drug treatment, especially when tis-
sue biopsy is not possible. Multiple studies
are under way for early diagnosis, monitor-
ing of tumor recurrence, evaluation of treat-
ment response, and identification of emerg-
ing targets or resistance indicators during
disease progression ( 6 , 7 ).
CTCs are heterogeneous live cells in blood;
some retain the capability of seeding or re-
seeding metastases and thereby contribute
to increased metastatic growth. Ebright et
al. provide a singular approach to determin-
ing metastatic CTC subsets: They captured
CTCs from patients with hormone receptor–
positive (HR+) metastatic breast cancer, the
most common subtype. They cultured the
CTCs and transduced them with a library
of single guide RNAs to allow genome-wide
transcriptional activation (CRISPRa) ( 8 ).
The cells were then injected in mice, and the
highly expressed genes that were associated
with lung metastases were identified. They
found expected genes, such as oncogenes or
those involved in transcriptional and trans-
lational regulation, cell motility, and cell cy-
cle progression. But they also unexpectedly
found that metastatic CTCs expressed genes
encoding multiple RPs, which were associ-
ated with increased global translation.
Human cells show plasticity. Epithelial-
to-mesenchymal transition in cancer is a
state whereby epithelial cells lose cell po-
larity and cell adhesion proteins, becoming
more invasive and migratory—an important
step in metastasis. Mesenchymal-like cells
may revert by mesenchymal-to-epithelial
transition, gaining epithelial properties as
they integrate and grow in distant organs.
CTCs and CTC clusters are heterogeneous
even in the same blood sample ( 9 ) and may
show epithelial, mesenchymal, and hybrid
phenotypes ( 10 , 11 ). Ebright et al. found
that high RP–expressing CTCs captured
from the blood of patients with HR+ breast
cancer showed increased expression of epi-
thelial markers and decreased expression
of mesenchymal markers, and that these
patients had worse overall survival. Their
work implies that epithelial cell fate may be
associated with higher ribosomal content
and a greater propensity for metastasis.
When CTC cell lines were transduced to
overexpress specific RPs and then injected
into the tail veins of mice, metastases devel-
CANCER
Deciphering cancer clues from blood
Circulating tumor cells are accessible indicators of real-time cancer biology
Primary tumor
with cellular
heterogeneity
Metastatic
tumor cells
seed additional
metastases
CTCs seed
metastases
into distant
organs
Tumor cell
clones
Cell-free
nucleic
acids
Extracellular
vesicles
CTC cluster
Blood
sample
containing
CTCs
Department of Surgery, Stanford University School of
Medicine, Stanford, CA, USA. Email: [email protected]
INSIGHTS | PERSPECTIVES
1424 27 MARCH 2020 • VOL 367 ISSUE 6485
A snapshot of metastatic cancer biology
Tumor-associated cells and products intravasate into the bloodstream, circulate, extravasate into tissues,
and enable metastatic tumor growth in distant organs. Circulating tumor cells (CTCs) captured from a blood
sample reflect the diversity of cells from a primay tumor and different metastases.