To the Editor:
The myelodysplastic syndromes (MDS) are common myeloid malignancies characterized
by ineffective hematopoiesis and blood cytopenias, with patients showing increasing
bone marrow blasts with disease progression [1]. Mutations in genes involved in pre-mRNA
splicing (SF3B1, SRSF2, U2AF1, and ZRSR2) are the most common mutations found in MDS,
occurring in over 50% of all cases [2–4]. There is evidence that some spliceosome
components play a role in the maintenance of genomic stability [5]. Splicing is a
transcription coupled process; splicing factor mutations affect transcription and
may lead to the accumulation of R-loops (RNA-DNA hybrids with a displaced single stranded
DNA) [6]. Mutations in the splicing factors SRSF2 and U2AF1 have been recently shown
to increase R-loop formation in leukemia cell lines, resulting in increased DNA damage,
replication stress, and activation of the ATR-Chk1 pathway [7, 8]. SF3B1 is the most
frequently mutated splicing factor gene in MDS, with mutations occurring in 25–30%
of MDS patients [9–11]. SF3B1 mutations are also found at lower frequency in other
hematological malignancies [4, 11] and in some individuals with clonal hematopoiesis
of indeterminate potential [12]. A role of SF3B1 mutations in R-loop accumulation
and DNA damage has not yet been reported in hematopoietic cells. Here, we investigated
the effects of SF3B1 mutations on R-loop formation and associated DNA damage response
in MDS and leukemia cells, and we also explored potential therapeutic implications.
Firstly, we investigated the effects of SF3B1 mutations on the formation of R-loops,
as measured by immunofluorescence staining using the S9.6 antibody (Supplementary
Materials and Methods) [7]. K562 cells (a myeloid leukemia cell line) with the SF3B1K700E
mutation showed a significant increase in the number of S9.6 foci, indicating increased
R-loops, compared with isogenic SF3B1K700K K562 cells (Fig. 1a, S1A). We then analyzed
induced pluripotent stem cells (iPSCs) that we generated (and characterized, Fig. S2)
from bone marrow CD34+ cells of one SF3B1 mutant MDS patient and of one healthy control
(Supplementary Materials and Methods). A significant increase in R-loops was observed
in an iPSC clone harboring the SF3B1 mutation compared with another iPSC clone without
the SF3B1 mutation obtained from same MDS patient, and to iPSCs from the healthy control
(Fig. 1b). We have also analyzed the levels of R-loops in the bone marrow CD34+ cells
from three SF3B1 mutant MDS patients, three splicing factor wildtype MDS patients,
and three healthy controls. Importantly, CD34+ cells from SF3B1 mutant MDS patients
(Table S1) showed a significant and marked increase in R-loops compared with CD34+
cells from MDS patients without splicing factor mutations (2.4-fold) and from healthy
controls (2.6-fold) (Fig. 1c, S1B). Our results demonstrate that an accumulation of
R-loops occurs in association with the presence of SF3B1 mutations in MDS and leukemia
cells.
Fig. 1
SF3B1 mutation leads to increased R-loops and associated DNA damage response.
Quantitative analysis of S9.6 foci detected by immunocytochemistry in (a) SF3B1K700K
and SF3B1K700E K562 cells (n > 300 cells/category) (b) iPSC clones generated from
an MDS patient sample with SF3B1 mutation (MDS SF3B1Mut: iPSC clone harboring the
SF3B1 mutation; MDS SF3B1WT: iPSC clone without the SF3B1 mutation) and from a healthy
control (n > 150 cells/category) (c) CD34+ cells from MDS patients with SF3B1 mutation
(MDS SF3B1Mut), from MDS patients without splicing factor mutations (MDS SFWT), and
from healthy controls (n > 300 cells/category). Quantitative analysis of γ-H2AX foci
detected by immunocytochemistry in (d) SF3B1K700K and SF3B1K700E K562 cells (n > 300
cells/category) (e) iPSC clones generated from an MDS patient sample with SF3B1 mutation
(MDS SF3B1Mut: iPSC clone harboring the SF3B1 mutation; MDS SF3B1WT: iPSC clone without
the SF3B1 mutation) and from a healthy control (n > 100 cells/category) (f) CD34+
cells from MDS patients with SF3B1 mutation (MDS SF3B1Mut), from MDS patients without
splicing factor mutations (MDS SFWT), and from healthy controls (n > 150 cells/category).
g Quantitative data and h representative images of S9.6 foci detected by immunocytochemistry
in SF3B1K700K-EV, SF3B1K700E-EV, SF3B1K700E-RNaseH-WT, and SF3B1K700E-RNaseH-WKKD
K562 cells (n > 300 cells/category). Green- S9.6; blue- DAPI. i Quantitative analysis
and j representative images of γ-H2AX foci in SF3B1K700K-EV, SF3B1K700E-EV, and SF3B1K700E-RNaseH-WT
K562 cells (n > 150 cells/category). Red- γ-H2AX; blue: DAPI. All values are plotted
as mean ± SEM. P values in a and d were obtained using the unpaired Student’s T test.
P values in b–c, e–g, i were obtained using one-way ANOVA with the Tukey’s multiple
comparisons test. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001. Scale bar −10 µm.
We then investigated the effects of SF3B1 mutations on the DNA damage response, as
measured by immunofluorescence staining using anti-γ-H2AX antibody (Supplementary
Materials and Methods) [7]. K562 cells with the SF3B1K700E mutation showed a significant
increase in the number of γ-H2AX foci, indicating increased DNA damage, compared with
isogenic control SF3B1K700K K562 cells (Fig. 1d, S3A). Similarly, an iPSC clone harboring
the SF3B1 mutation showed increased DNA damage as compared with another iPSC clone
without the SF3B1 mutation obtained from same MDS patient and to iPSCs from a healthy
control (Fig. 1e). Bone marrow CD34+ cells from SF3B1 mutant MDS patients showed significantly
increased DNA damage compared with CD34+ cells from MDS patients without splicing
factor mutations and from healthy controls (Fig. 1f, S3B).
To investigate whether the observed DNA damage in SF3B1 mutant K562 cells results
from induced R-loops, we overexpressed RNaseH1 (encoding an enzyme that degrades the
RNA in RNA:DNA hybrids) to resolve R-loops in these cells. RNaseH1 overexpression
significantly reduced the number of S9.6 foci in SF3B1K700E K562 cells compared with
SF3B1K700E K562 cells expressing an empty vector (Fig. 1g, h). Furthermore, SF3B1K700E
K562 cells expressing WKKD mutant RNaseH1 (lacking hybrid binding and RNaseH1 activity)
did not show a decrease in the number of S9.6 foci (Fig. 1g, h). RNaseH1 overexpression
also significantly reduced the number of γ-H2AX foci (Fig. 1i, j) in SF3B1K700E K562
cells compared with SF3B1K700E K562 cells expressing an empty vector. Further, western
blot analysis of γ-H2AX levels in SF3B1K700E K562 cells expressing RNaseH1 also showed
decreased levels of γ-H2AX (Fig. S4). These data demonstrate that increased levels
of R-loops result in increased DNA damage in SF3B1 mutant leukemia cells.
Next, to investigate the signaling events related to DNA damage in SF3B1 mutant cells,
we have studied ATR and ATM signaling, two pathways that are frequently activated
following DNA damage [13]. The ATR signaling pathway was analyzed by measuring the
levels of Chk1 phosphorylation at Ser345, a hallmark of activation of the ATR pathway,
in K562 cells (Supplementary Materials and Methods). We observed increased phosphorylation
of Chk1 in K562 cells with the SF3B1K700E mutation compared with isogenic SF3B1K700K
K562 cells (Fig. S5A). Suppression of R-loops by RNaseH1 overexpression resulted in
decreased Chk1 phosphorylation, indicating suppression of ATR pathway activation in
SF3B1K700E K562 cells (Fig. S5A). In contrast, we did not observe activation of the
ATM signaling pathway in the SF3B1K700E K562 cells as analyzed by measuring the levels
of ATM phosphorylation at Ser1981, Chk2 phosphorylation at Thr68, and RPA32 phosphorylation
at Ser4/8 (Fig. S5B). These data demonstrate that SF3B1 mutations are associated with
downstream activation of ATR but not ATM signaling.
We sought to explore the functional importance of ATR activation associated with SF3B1
mutation and determine whether this could represent a therapeutic vulnerability. We
evaluated the sensitivity of SF3B1 mutant cells to VE-821 (Supplementary Materials
and Methods). SF3B1K700E K562 cells showed preferential sensitivity to the ATR inhibitor
VE-821 compared with isogenic SF3B1K700K K562 cells (Fig. S6A). Chk1 is a critical
substrate of ATR, and we next chose to investigate the effects of Chk1 inhibition
in SF3B1K700E K562 cells. Interestingly, SF3B1K700E K562 cells demonstrated preferential
sensitivity to the Chk1 inhibitor UCN-01 compared with SF3B1K700K K562 cells, suggesting
that ATR-Chk1 activation is important for the survival of SF3B1 mutant cells (Fig. 2a).
The effect of RNaseH1 overexpression on the sensitivity of SF3B1K700E K562 cells towards
UCN-01 was also examined. We found that the sensitivity of SF3B1K700E K562 towards
UCN-01 decreased after overexpressing RNaseH1 (Fig. S6B). Treatment with an ATM inhibitor
(KU-55933) did not show a significant difference in the sensitivity of SF3B1K700E
K562 cells compared with isogenic SF3B1K700K K562 cells (Fig. S6C). Notably, bone
marrow CD34+ cells from SF3B1 mutant MDS patients showed preferential sensitivity
towards UCN-01 (Fig. 2b) and VE-821 (Fig. 2c) compared with CD34+ cells from MDS patients
without splicing factor mutations and from healthy controls. These results show that
activation of ATR, but not ATM, plays an important role for the survival of SF3B1
mutant cells, and that these cells are vulnerable to Chk1 inhibition.
Fig. 2
SF3B1 mutant cells are preferentially sensitive to UCN-01, VE-821, and Sudemycin D6
and the effects of UCN-01 and VE-821 were synergistically enhanced by Sudemycin D6.
a Viability of SF3B1K700K and SF3B1K700E K562 cells treated with UCN-01. IC50 obtained
for SF3B1K700K and SF3B1K700E K562 cells are 260.8 ± 1.05 nM and 61.53 ± 1.1 nM, respectively
(n = 3). Effect of (b) UCN-01 and (c) VE-821 treatment on viability of CD34+ cells
from MDS SF3B1Mut (n = 4), from MDS SFWT (n = 3), and from healthy controls (n = 4).
d Viability of SF3B1K700K and SF3B1K700E K562 cells treated with the splicing modulator
Sudemycin D6. IC50 obtained for SF3B1K700K and SF3B1K700E K562 cells are 87.8 ± 1.09 nM
and 41.1 ± 1.15 nM, respectively (n = 3). e Effect of Sudemycin D6 on viability of
CD34+ cells from MDS SF3B1Mut (n = 4), from MDS SFWT (n = 3), and from healthy control
(n = 4). Effect of combination of different doses of (f) Sudemycin D6 and UCN-01 (n = 2)
and (g) Sudemycin D6 and VE-821 (n = 2) on viability of SF3B1K700K and SF3B1K700E
K562 cells. Effect of combination of (h) Sudemycin D6 (35 nM) and UCN-01 (35 nM) and
(i) Sudemycin D6 (35 nM) and VE-821 (5 µM) on viability of CD34+ cells from MDS SF3B1Mut
(n = 3), from MDS SFWT (n = 2), and from healthy controls (n = 3). All values are
plotted as mean ± SEM. Results shown in a and d were analyzed by using nonlinear regression.
P values for b–c, e, h–i are calculated using one-way ANOVA with the Tukey’s multiple
comparisons test. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001.
Preferential sensitivity of splicing factor mutant cells towards splicing modulators
has been reported previously [4, 14, 15]. Thus, we investigated whether a splicing
modulator could increase the sensitivity of SF3B1 mutant cells to ATR or Chk1 inhibition.
The splicing modulator Sudemycin D6 has been shown to preferentially kill U2AF1 mutant
cells [14], but its effects on myeloid leukemia cells with the SF3B1 mutation have
not been evaluated. Here, we showed that SF3B1K700E K562 cells were preferentially
sensitive to Sudemycin D6 compared with isogenic SF3B1K700K K562 cells (Fig. 2d).
Bone marrow CD34+ cells from SF3B1 mutant MDS patients showed preferential sensitivity
to Sudemycin D6 compared with CD34+ cells from MDS patients without splicing factor
mutations and from healthy controls (Fig. 2e). We then tested the effects of Sudemycin
D6 in combination with an ATR inhibitor or a Chk1 inhibitor. The effects of VE-821
and UCN-01 on SF3B1 mutant K562 cells were enhanced by Sudemycin D6 (Fig. 2f, g).
We have also determined the synergy scores of Sudemycin D6 and UCN-01 (Fig. S7A, B),
and Sudemycin D6 and VE-821 (Fig. S7C, D) on SF3B1K700K and SF3B1K700E K562 cells.
Various dose combinations showed a positive synergy score (δ-score), indicating synergy
of Sudemycin D6 with VE-821 and UCN-01, with higher scores for SF3B1K700E K562 cells.
Importantly, bone marrow CD34+ cells from SF3B1 mutant MDS patients also showed preferential
sensitivity towards the combination of Sudemycin D6 with UCN-01 (Fig. 2h) or with
VE-821 (Fig. 2i).
In summary, we show for the first time that mutations of SF3B1, the most commonly
mutated splicing factor gene in MDS [2, 3, 9, 11], lead to the accumulation of R-loops
and associated DNA damage, resulting in activation of the ATR pathway in MDS and leukemia
cells. The suppression of R-loops rescued cellular defects including DNA damage and
ATR-Chk1 activation. Our current study on mutant SF3B1, and previous studies by others
on mutant U2AF1 and SRSF2 [7, 8], together demonstrate that different mutated splicing
factors in hematopoietic cells all have convergent effects on R-loop elevation leading
to DNA damage. It is possible that this R-loop induced DNA damage may give rise to
deleterious mutations in MDS hematopoietic stem and progenitor cells, contributing
to the clonal advantage of splicing factor mutant cells in human bone marrow. Future
studies seeking to compare R-loop levels in the CD34+ cells of SF3B1 mutant MDS cases
with those in CD34+ cells of MDS patients with mutations of other splicing factors
(SRSF2, U2AF1, ZRSR2) are warranted.
This is the first study showing that splicing factor mutant MDS and leukemia cells
are preferentially sensitive to the Chk1 inhibitor UCN-01, suggesting that Chk1 inhibition,
alone or in combination with splicing modulators, may represent a novel therapeutic
strategy to target splicing factor mutant cells. This strategy could also be potentially
extended to therapeutically target other types of cancers known to harbor SF3B1 mutations.
This study provides preclinical evidence that MDS patients with spliceosome mutations
may benefit from Chk1 inhibition to exploit the R-loop-associated vulnerability induced
by these mutations.
Supplementary information
Supplementary Materials and Methods
Table S1
Supplementary Figure Legends
Figure S1
Figure S2
Figure S3
Figure S4
Figure S5
Figure S6
Figure S7