stromal
cells,
which
were
able
to
myeloid
colony-forming
[1]. Moreover, Coculture of hPSCs with OP9 bone marrow stro-
mal cells or with mAGM-S3 can also generation of multilineage
HSPCs [3, 5, 6]. The differentiation efficiency of embryoid bodies
(EBs)-based model is low due to the heterogeneity of cell types and
the lack of access to nutrients of internal cells [7]. Additionally,
coculture with mouse feeder cells leads to human cells coming into
contact with cells of foreign species, which may be detrimental to
subsequent therapeutic applications.
Hematopoietic differentiation from hPSCs in chemically
defined systems were also developed [6, 8], but often involves
culturing in specialized medium and many steps of the differentia-
tion, which make the cost of HPSCs very expensive and it is difficult
to produce the large-scale of HPSCs. To promote hematopoietic
differentiation of hPSCs, the proper use of growth factors and
cytokines to benefit the production of HSPCs were investigated.
Kennedy et al. reported that inhibition of Nodal/Activin pathway
during hematopoiesis from human ESCs in a chemically defined
medium containing the SB-431542, can induce the development
of definitive HSPCs and blocked the primitive hematopoiesis pro-
cess [9]. The canonical Wnt pathway is also known to play a vital
role in the induction of definitive HPSCs derived from human
ESCs [10]. Treatment of human ESCs with GSK-3 inhibitor
CHIR99021 by activation of canonical Wnt signaling can promote
definitive hematopoiesis and inhibited the number of primitive
HSPCs
[11].
In
contrast,
treating
human
ESCs
with the
Wnt-antagonist
IWP2
augmented
the
number
of
primitive
HSPCs. In keeping with this study, Wang et al. reported that
R-spondin2 plays a key role in early hematopoietic differentiation
of hPSCs that increased the generation of APLNR+ mesoderm cells
by activating TGF beta signaling [12]. In another approach, ectopic
expression of transcription factors promotes the hematopoietic
commitment of hPSCs by increasing the expression of mesoderm,
hemogenic endothelial and the genes associated with hematopoie-
tic development. Ran et al. demonstrated that expression of endog-
enous RUNX1a promotes hematopoietic lineage commitment
from hPSCs and enhanced definitive hematopoiesis [13]. It has
also been shown that ectopic expression of HOXA9 increased
hematopoietic
commitment
from
human
ESCs;
however,
HOXA9 was not sufficient to confer in vivo long-term engraftment
potential [14]. Interesting, a recent study reported that suppression
of MSX2 enhances hematopoietic differentiation of hPSCs via inhi-
bition of TGF beta signaling [15].
Recent work has indicated the importance of the local physical
environment (such as blood flow, wall shear stress) in regulating
HE specification and HSPC production [16–18]. To mimic the
physical microenvironment, some bioengineering techniques that
promote
hematopoiesis
from
hPSCs
have
been
applied
[19, 20]. Additionally, the combination of bioreactors and
56
Xiaohua Lei et al.