BMP4/Smad5 dependent stress erythropoiesis is required for the expansion of erythroid progenitors during fetal development

The rapid growth of the embryo places severe demands on the ability of the cardiovascular system to deliver oxygen to cells. To meet this need, erythroid progenitors rapidly expand in the fetal liver microenvironment such that by E14.5, erythropoiesis predominates in the fetal liver. In this report we show that the BMP4/Smad5 dependent stress erythropoiesis pathway plays a key role in the expansion of erythroid progenitors in the fetal liver. These data show that the fetal liver contains two populations of erythroid progenitors. One population resembles the steady state erythroid progenitors found in the adult bone marrow. While the second population exhibits the properties of stress erythroid progenitors found in adult spleen. Here we demonstrate that defects in BMP4/Smad5 signaling preferentially affect the expansion of the stress erythroid progenitors in the fetal liver leading to fetal anemia. These data suggest that steady state erythropoiesis is unable to generate sufficient erythrocytes to maintain the rapid growth of the embryo leading to the induction of the BMP4 dependent stress erythropoiesis pathway. These observations underscore the similarities between fetal erythropoiesis and stress erythropoiesis.     

Differential Processing of Amyloid-�� Precursor Protein Directs Human Embryonic Stem Cell Proliferation and Differentiation into Neuronal Precursor Cells

The amyloid-β precursor protein (AβPP) is a ubiquitously expressed transmembrane protein whose cleavage product, the amyloid-β (Aβ) protein, is deposited in amyloid plaques in neurodegenerative conditions such as Alzheimer disease, Down syndrome, and head injury. We recently reported that this protein, normally associated with neurodegenerative conditions, is expressed by human embryonic stem cells (hESCs). We now report that the differential processing of AβPP via secretase enzymes regulates the proliferation and differentiation of hESCs. hESCs endogenously produce amyloid-β, which when added exogenously in soluble and fibrillar forms but not oligomeric forms markedly increased hESC proliferation. The inhibition of AβPP cleavage by β-secretase inhibitors significantly suppressed hESC proliferation and promoted nestin expression, an early marker of neural precursor cell (NPC) formation. The induction of NPC differentiation via the non-amyloidogenic pathway was confirmed by the addition of secreted AβPPα, which suppressed hESC proliferation and promoted the formation of NPCs. Together these data suggest that differential processing of AβPP is normally required for embryonic neurogenesis.The amyloid-β precursor protein (AβPP)⁵ is a ubiquitously expressed transmembrane protein whose cleavage product, the amyloid-β (Aβ) protein, is deposited in amyloid plaques in the aged brain, following head injury, and in the neurodegenerative conditions of Alzheimer disease (AD) and Down syndrome (DS). AβPP has structural similarity to growth factors (1) and modulates several important neurotrophic functions, including neuritogenesis, synaptogenesis, and synaptic plasticity (2). The function of AβPP during early embryogenesis and neurogenesis has not been well described.AβPP is processed by at least two pathways, the non-amyloidogenic and amyloidogenic pathways. Non-amyloidogenic processing of AβPP yields secreted AβPPα (sAβPPα), the secreted extracellular domain of AβPP that acts as a growth factor for many cell types and promotes neuritogenesis (3). Amyloidogenic processing of AβPP releases sAβPPβ, the AβPP intracellular domain, and Aβ proteins. The Aβ protein has both neurotoxic and neurotrophic properties (4) dependent on the differentiation state of the neuron; Aβ is neurotoxic to differentiating neurons via a mechanism involving differentiation-associated increases in the phosphorylation of the microtubule-associated protein tau (5) but neurotrophic to undifferentiated embryonic neurons. Evidence supporting a neurotrophic function for Aβ during development include its neurogenic activity toward rat neural stem cells (4–6). Consistent with these data, two studies have demonstrated increased hippocampal neurogenesis in young transgenic mice overexpressing human APP_Sw,Ind (7, 8).Recently we reported that human embryonic stem cells (hESCs) express AβPP and that both the stemness of the cells and the pregnancy-associated hormone human chorionic gonadotropin alter AβPP expression (9). These results suggest a functional role for AβPP during early human embryogenesis. To further investigate the function of AβPP and its cleavage products during early embryonic neurogenesis, we examined the expression and processing of this protein and its role in proliferation and differentiation of hESCs into neural precursor cells (NPCs). We found that amyloidogenic processing of AβPP promotes hESC proliferation whereas non-amyloidogenic processing induces hESC differentiation into NPCs. These data reveal an important function for AβPP during early human embryonic neurogenesis. Our data imply that any dysregulation in AβPP processing that leads to altered sAβPPα/Aβ production could result in aberrant neurogenesis as reported in the AD and DS brains.     

Diffusion MRI Tractography of the Developing Human Fetal Heart

Objective

Human myocardium has a complex and anisotropic 3D fiber pattern. It remains unknown, however, when in fetal life this anisotropic pattern develops and whether the human heart is structurally fully mature at birth. We aimed here to use diffusion tensor MRI (DTI) tractography to characterize the evolution of fiber architecture in the developing human fetal heart.

Methods

Human fetal hearts (n = 5) between 10–19 weeks of gestation were studied. The heart from a 6-day old neonate and an adult human heart served as controls. The degree of myocardial anisotropy was measured by calculating the fractional anisotropy (FA) index. In addition, fiber tracts were created by numerically integrating the primary eigenvector field in the heart into coherent streamlines.

Results

At 10–14 weeks the fetal hearts were highly isotropic and few tracts could be resolved. Between 14–19 weeks the anisotropy seen in the adult heart began to develop. Coherent fiber tracts were well resolved by 19 weeks. The 19-week myocardium, however, remained weakly anisotropic with a low FA and no discernable sheet structure.

Conclusions

The human fetal heart remains highly isotropic until 14–19 weeks, at which time cardiomyocytes self-align into coherent tracts. This process lags 2–3 months behind the onset of cardiac contraction, which may be a prerequisite for cardiomyocyte maturation and alignment. No evidence of a connective tissue scaffold guiding this process could be identified by DTI. Maturation of the heart’s sheet structure occurs late in gestation and evolves further after birth.     

Friend virus utilizes the BMP4-dependent stress erythropoiesis pathway to induce erythroleukemia

More than 50 years of genetic analysis has identified a number of host genes that are required for the expansion of infected cells during the progression of Friend-virus-induced erythroleukemia. In this report, we show that Friend virus induces the bone morphogenetic protein 4 (BMP4)-dependent stress erythropoiesis pathway in the spleen, which rapidly amplifies target cells, propagating their infection and resulting in acute splenomegaly. This mechanism mimics the response to acute anemia, in which BMP4 expressed in the spleen drives the expansion of a specialized population of stress erythroid progenitors. Previously we demonstrated that these progenitors, termed stress BFU-E, are targets for Friend virus in the spleen (A. Subramanian, H. E. Teal, P. H. Correll, and R. F. Paulson, J. Virol. 79:14586-14594, 2005). Here, we extend those findings by showing that Friend virus infects two distinct populations of bone marrow cells. One population, when infected, differentiates into mature erythrocytes in an Epo-independent manner, while a second population migrates to the spleen after infection, where it induces BMP4 expression and acts as a reservoir of virus. The activation of the stress erythropoiesis pathway in the spleen by Friend virus results in the rapid expansion of stress BFU-E, providing abundant target cells for viral infection. These observations suggest a novel mechanism by which a virus induces a stress response pathway that amplifies target cells for the virus, leading to acute expansion of infected cells.     

Amyloid-beta precursor protein expression and modulation in human embryonic stem cells: a novel role for human chorionic gonadotropin

The amyloid-β precursor protein (AβPP) is a ubiquitously expressed adhesion and neuritogenic protein whose processing has previously been shown to be regulated by reproductive hormones including the gonadotropin luteinizing hormone (LH) in human neuroblastoma cells. We report for the first time the expression of AβPP in human embryonic stem (hES) cells at the mRNA and protein levels. Using N- and C-terminal antibodies against AβPP, we detected both the mature and immature forms of AβPP as well as truncated variants (∼53 kDa, 47 kDa, and 29 kDa) by immunoblot analyses. Expression of AβPP is regulated by both the stemness of the cells and pregnancy-associated hormones. Addition of human chorionic gonadotropin, the fetal equivalent of LH that is dramatically elevated during pregnancy, markedly increased the expression of all AβPP forms. These results indicate a critical molecular signaling link between the hormonal environment of pregnancy and the expression of AβPP in hES cells that is suggestive of an important function for this protein during early human embryogenesis prior to the formation of neural precursor cells.