Regulation of hematopoietic and leukemic stem cells by the immune system

Hematopoietic stem cells (HSCs) are rare, multipotent cells that generate via progenitor and precursor cells of all blood lineages. Similar to normal hematopoiesis, leukemia is also hierarchically organized and a subpopulation of leukemic cells, the leukemic stem cells (LSCs), is responsible for disease initiation and maintenance and gives rise to more differentiated malignant cells. Although genetically abnormal, LSCs share many characteristics with normal HSCs, including quiescence, multipotency and self-renewal. Normal HSCs reside in a specialized microenvironment in the bone marrow (BM), the so-called HSC niche that crucially regulates HSC survival and function. Many cell types including osteoblastic, perivascular, endothelial and mesenchymal cells contribute to the HSC niche. In addition, the BM functions as primary and secondary lymphoid organ and hosts various mature immune cell types, including T and B cells, dendritic cells and macrophages that contribute to the HSC niche. Signals derived from the HSC niche are necessary to regulate demand-adapted responses of HSCs and progenitor cells after BM stress or during infection. LSCs occupy similar niches and depend on signals from the BM microenvironment. However, in addition to the cell types that constitute the HSC niche during homeostasis, in leukemia the BM is infiltrated by activated leukemia-specific immune cells. Leukemic cells express different antigens that are able to activate CD4⁺ and CD8⁺ T cells. It is well documented that activated T cells can contribute to the control of leukemic cells and it was hoped that these cells may be able to target and eliminate the therapy-resistant LSCs. However, the actual interaction of leukemia-specific T cells with LSCs remains ill-defined. Paradoxically, many immune mechanisms that evolved to activate emergency hematopoiesis during infection may actually contribute to the expansion and differentiation of LSCs, promoting leukemia progression. In this review, we summarize mechanisms by which the immune system regulates HSCs and LSCs.     

Spatial differences in hematopoiesis but not in stem cells indicate a lack of regional patterning in definitive hematopoietic stem cells

Most tissues are patterned so that progenitors in different locations are programmed to have different properties. Stem cells from different regions of the nervous system acquire intrinsic differences in their properties as they migrate through distinct environments. Hematopoietic stem cells (HSCs) also migrate through diverse environments throughout life, raising the question of whether HSCs also acquire at least transient changes in their properties as they are exposed to diverse environments. Although we observed significant differences in hematopoiesis between the fetal liver and fetal spleen, we were not able to detect phenotypic, functional, or gene expression differences between the HSCs in these organs. Regional differences in definitive hematopoiesis are therefore not determined by regional differences between HSCs. We were also not able to detect phenotypic, functional, or gene expression differences between HSCs in different adult bone marrow compartments. Our failure to detect differences among stem cells from different regions of the hematopoietic system at the same time during development suggests that the hematopoietic system has evolved mechanisms to prevent the spatial reprogramming of HSC properties as they migrate between distinct environments.     

Amphibian immune defenses against chytridiomycosis: impacts of changing environments

Eco-immunology is the field of study that attempts to understand the functions of the immune system in the context of the host's environment. Amphibians are currently suffering devastating declines and extinctions in nearly all parts of the world due to the emerging infectious disease chytridiomycosis caused by the chytrid fungus, Batrachochytrium dendrobatidis. Because chytridiomycosis is a skin infection and remains confined to the skin, immune defenses of the skin are critical for survival. Skin defenses include secreted antimicrobial peptides and immunoglobulins as well as antifungal metabolites produced by symbiotic skin bacteria. Low temperatures, toxic chemicals, and stress inhibit the immune system and may impair natural defenses against B. dendrobatidis. Tadpoles' mouth parts can be infected by B. dendrobatidis. Damage to the mouth parts can impair growth, and the affected tadpoles maintain the pathogen in the environment even when adults have dispersed. Newly metamorphosing frogs appear to be especially vulnerable to infection and to the lethal effects of this pathogen because the immune system undergoes a dramatic reorganization at metamorphosis, and postmetamorphic defenses are not yet mature. Here we review our current understanding of amphibian immune defenses against B. dendrobatidis and the ability of the pathogen to resist those defenses. We also briefly review what is known about the impacts of temperature, environmental chemicals, and stress on the host-pathogen interactions and suggest future directions for research.     

Local signals in stem cell-based bone marrow regeneration

The cellular basis of bone marrow （BM） tissue development and regeneration is mediated through hematopoietic stem cells （HSCs） and mesenchymal stem cells （MSCs）. Local interplays between hematopoietic cells and BM stromal cells （BMSCs） determine the reconstitution of hematopoiesis after myelosuppression. Here we review the BM local signals in control of BM regeneration after insults. Hematopoietic growth factors （HGFs） and cytokines produced by BMSCs are primary factors in regulation ofBM hematopoiesis. Morphogens which are critical to early embryo development in multiple species have been added to the family of HSCs regulators, including families of Wnt proteins, Notch ligands, BMPs, and Hedgehogs. Global gene expression analysis of HSCs and BMSCs has begun to reveal signature groups of genes for both cell types. More importantly, analysis of global gene expression coupled with biochemical and biological studies of local signals during BM regeneration have strongly suggested that HGFs and cytokines may not be the primary local regulators for BM recovery, rather chemokines （SDF- 1, FGF-4） and angiogenic growth factors （VEGF-A, Ang- 1） play instructive roles in BM reconstitution after myelosuppression. A new direction of management of BM toxicity is emerging from the identification of BM regenerative regulators.     

Innate immune recognition of respiratory syncytial virus infection

Respiratory syncytial virus (RSV) is the leading cause of respiratory infection in infants and young children. Severe clinical manifestation of RSV infection is a bronchiolitis, which is common in infants under six months of age. Recently, RSV has been recognized as an important cause of respiratory infection in older populations with cardiovascular morbidity or immunocompromised patients. However, neither a vaccine nor an effective antiviral therapy is currently available. Moreover, the interaction between the host immune system and the RSV pathogen during an infection is not well understood. The innate immune system recognizes RSV through multiple mechanisms. The first innate immune RSV detectors are the pattern recognition receptors (PRRs), including toll-like receptors (TLRs), retinoic acid-inducible gene-I (RIG-I)-like receptors (RLRs), and nucleotide-biding oligomerization domain (NOD)-like receptors (NLRs). The following is a review of studies associated with various PRRs that are responsible for RSV virion recognition and subsequent induction of the antiviral immune response during RSV infection. [BMB Reports 2014; 47(4): 184-191]     

Photoperiod alters macrophage responsiveness, but not expression of Toll-like receptors in Siberian hamsters

Defense against pathogens is a critical component of comparative and ecological biology. However, pathogen recognition, a process necessary for the facilitation of systemic immune response, remains understudied in a comparative context, yet could provide insight into how the immune system interacts with pathogens in variable environments. We examined pathogen recognition by macrophages in relation to an ecological variable, day length, in Siberian hamsters (Phodopus sungorus). Because peritoneal macrophages collected in long, summer-like day lengths are more responsive to a lipopolysaccharide (LPS) challenge compared to macrophages collected during short, winter-like day lengths, we hypothesized that these functional differences are mediated by variation in pathogen recognition, which occurs through binding to Toll-like receptors (TLRs). We predicted that expression of TLR2 and 4, the receptors that bind and respond specifically to LPS, would be upregulated in long vs. short days, and that expression of these receptors would reflect macrophage responsiveness to LPS. Macrophages collected during long days were again more responsive to LPS challenge compared to short-day macrophages; however, TLR2 and TLR4 expression was similar between photoperiods and were unrelated to our measure of macrophage responsiveness suggesting that other downstream intracellular mechanisms may be responsible for photoperiod-based variation in macrophage responsiveness in this species.     

Unique and independent roles for MLL in adult hematopoietic stem cells and progenitors

The Mixed Lineage Leukemia (MLL) gene is essential for embryonic hematopoietic stem cell (HSC) development, but its role during adult hematopoiesis is unknown. Using an inducible knockout model, we demonstrate that Mll is essential for the maintenance of adult HSCs and progenitors, with fatal bone marrow failure occurring within 3 weeks of Mll deletion. Mll-deficient cells are selectively lost from mixed bone marrow chimeras, demonstrating their failure to self-renew even in an intact bone marrow environment. Surprisingly, HSCs lacking Mll exhibit ectopic cell-cycle entry, resulting in the depletion of quiescent HSCs. In contrast, Mll deletion in myelo-erythroid progenitors results in reduced proliferation and reduced response to cytokine-induced cell-cycle entry. Committed lymphoid and myeloid cells no longer require Mll, defining the early multipotent stages of hematopoiesis as Mll dependent. These studies demonstrate that Mll plays selective and independent roles within the hematopoietic system, maintaining quiescence in HSCs and promoting proliferation in progenitors.     

Understanding leukemic hematopoiesis as a complex adaptive system

Normal and abnormal hematopoiesis is working as a complex adaptive system. From this perspective, the development and the behavior of hematopoietic cell lineages appear as a balance between normal and abnormal hematopoiesis in the setting of a functioning or malfunctioning microenvironment under the control of the immune system and the influence of hereditary and environmental events.     

CD81 is essential for the re-entry of hematopoietic stem cells to quiescence following stress-induced proliferation via deactivation of the Akt pathway

The regulatory mechanisms governing the cell cycle progression of hematopoietic stem cells (HSCs) are well characterized, but those responsible for the return of proliferating HSCs to a quiescent state remain largely unknown. Here, we present evidence that CD81, a tetraspanin molecule acutely responsive to proliferative stress, is essential for the maintenance of long-term repopulating HSCs. Cd81(-/-) HSCs showed a marked engraftment defect when transplanted into secondary recipient mice and a significantly delayed return to quiescence when stimulated to proliferate with 5-fluorouracil (5FU). In addition, we found that CD81 proteins form a polarized patch when HSCs are returning to quiescence. Thus, we propose that the spatial distribution of CD81 during the HSC recovery phase drives proliferative HSC to quiescence, and is important to preserve the self-renewal properties. Here, we show that lack of CD81 leads to loss of HSC self-renewal, and the clustering of CD81 on HSC membrane results in deactivation of Akt, which subsequently leads to nuclear translocation of FoxO1a. Thus, CD81 functions as part of a previously undefined mechanism that prohibits excessive proliferation of HSCs exposed to environmental stress.     

Hematopoietic stem cell aging and self-renewal

A functional decline of the immune system occurs during organismal aging that is attributable, in large part, to changes in the hematopoietic stem cell (HSC) compartment. In the mouse, several hallmark age-dependent changes in the HSC compartment have been identified, including an increase in HSC numbers, a decrease in homing efficiency, and a myeloid skewing of differentiation potential. Whether these changes are caused by gradual intrinsic changes within individual HSCs or by changes in the cellular composition of the HSC compartment remains unclear. However, of note, many of the aging properties of HSCs are highly dependent on their genetic background. In particular, the widely used C57Bl/6 strain appears to have unique HSC aging characteristics compared with those of other mouse strains. These differences can be exploited by using recombinant inbred strains to further our understanding of the genetic basis for HSC aging. The mechanism(s) responsible for HSC aging have only begun to be elucidated. Recent studies have reported co-ordinated variation in gene expression of HSCs with age, possibly as a result of epigenetic changes. In addition, an accumulation of DNA damage, in concert with an increase in intracellular reactive oxygen species, has been associated with aged HSCs. Nevertheless, whether age-related changes in HSCs are programmed to occur in a certain predictable fashion, or whether they are simply an accumulation of random changes over time remains unclear. Further, whether the genetic dysregulation observed in old HSCs is a cause or an effect of cellular aging is unknown. We are grateful for the generous financial support provided by the Dutch Platform for Tissue Engineering (to B.D.) and for a VICI grant awarded by the Netherlands Organization for Scientific Research (to G.d.H.).     

On Leukocytes in Mammary Development and Cancer

During metastasis, tumor cells may be copying a program that is executed by hematopoietic stem cells during development.That cancer is development gone awry is not a new concept. Most of the “hallmarks” ascribed to cancer—proliferation, invasion and induction of blood vessel growth—also occur during organogenesis and development. Therefore, tumors are not necessarily learning new tricks during their development, but how about when they metastasize? In colonizing a new organ, often with some degree of specificity, tumor cells may simply be copying a program that is executed during development by hematopoietic stem cells (HSCs)—the stem cells that ultimately generate all of the cells in our blood and maintain its homeostasis. One family of cells generated by HSCs—leukocytes—is the focus of the work by Coussens and Pollard (2012). These two scientists have woven together several studies that revolutionized the way we think of immune cells. As pointed out by the investigators (whose respective laboratories are responsible for much of the seminal work on this subject), immune cells also have a variety of trophic functions, and it is these functions that are used rationally during development, and recklessly during tumor growth.This leads us back to metastasis. There is so much to learn about why a tumor travels from one organ to another, how it does so, and the manner by which it adapts to and ultimately flourishes (or fails) in a foreign microenvironment. And as stated above, immune cell precursors, HSCs, do the same. In the mouse, HSCs have originated in one tissue (the dorsal aorta), traveled to another (the placenta) via the circulation, and matured somewhere else (the liver)—all before birth. Finally, HSCs make their way to the bone marrow, where they reside postnatally. Specialized niches in the bone marrow are thought to mediate HSC dormancy as a means to preserve the “stemness” of this population, and there are mechanisms in place that allow these cells to rapidly exit these environs and proliferate in response to injury. Therefore, it should not come as a surprise that a common site where micrometastases are found is the bone marrow for many cancers (including that of the breast).Uncovering whether the same niches that control HSC expansion in the bone marrow are also responsible for maintaining quiescence of tumor cell populations is an exciting prospect, as is deciphering the precise components of these niches. Such work could explain the seemingly incongruous observation that despite an absence of clinically detectable disease, circulating tumor cells are present in the blood of post-treatment cancer patients sometimes even decades later! Perhaps the niches that regulate prolonged dormancy of tumors are dynamic and inhibit tumor proliferation while allowing them to mobilize periodically, much like for HSCs. It also stands to reason that loss of the same controls that prevent HSC expansion until systemic damage occurs could awaken dormant tumors.Shiozawa et al. (2011) have demonstrated that prostate cancer cells do in fact compete with HSCs for niches within the bone marrow, and that tumor cells are mobilized from HSC niches by similar mechanisms as for HSCs. Whether this is the case for other cancers and whether these similarities can be exploited therapeutically remain to be seen.So what more is there to be learned about immune cells? By furthering our understanding of how solid cancers mimic and hijack components of our immune system, we may not “cure” cancer, but we very well may uncover a means to suppress some cancers into a state of permanent dormancy.     

Regulation of dendritic cell differentiation and function by estrogen receptor ligands

Estrogen receptor (ER) ligands can modulate innate and adaptive immunity and hematopoiesis, which may explain the clear sex differences in immune responses during autoimmunity, infection or trauma. Dendritic cells (DC) are antigen presenting cells important for initiation of innate and adaptive immunity, as well as immune tolerance. DC progenitors and terminally differentiated DC express ER, indicating the ER ligands may regulate DC at multiple developmental and functional stages. Although there are profound differences in innate immunity between males and females or upon systemic imposition of sex hormones, studies are just beginning to link these differences to DC. Our and others studies demonstrate that estradiol and other ER ligands regulate the homeostasis of bone marrow myeloid and lymphoid progenitors of DC, as well as DC differentiation mediated by GM-CSF and Flt3 Ligand. Since DC have a brief lifespan, these data suggest that relatively short exposures to ER ligands in vivo will alter DC numbers and intrinsic functional capacity related to their developmental state. Studies in diverse experimental models also show that agonist and antagonist ER ligands modulate DC activation and production of inflammatory mediators. These findings have implications for human health and disease since they suggest that both DC development and functional capacity will be responsive to the physiological, pharmacological and environmental ER ligands to which an individual is exposed in vivo.     

Hematopoiesis leading to a diversity of dendritic antigen-presenting cell types

Hematopoietic stem cells (HSCs) undergo expansion and differentiation, giving rise to all terminally differentiated blood cells throughout life. HSCs are found in distinct anatomical sites during development, and in adults, hematopoiesis occurs predominantly on the luminal side of the bone cavity in bone marrow. Millions of newly formed blood cells are generated per second to accommodate the short half-life of hematopoietic cells. For this to happen, HSCs must sustain their self-renewal capacity as well as their capability to commit and differentiate toward multiple cell lineages. Development of the hematopoietic system is finely regulated as the animal ages, so that it does not become exhausted or misdirected. This review covers aspects of hematopoietic development from the embryonic period through adult life in relation to development of dendritic cells. It also considers a role for HSCs in extramedullary sites and their possible role in myelopoiesis, with formation of tissue-specific antigen-presenting cells.     

Dual role of Mpl receptor during the establishment of definitive hematopoiesis

Cytokine signaling pathways are important in promoting hematopoietic stem cell (HSC) self-renewal, proliferation and differentiation. Mpl receptor and its ligand, TPO, have been shown to play an essential role in the early steps of adult hematopoiesis. We previously demonstrated that the cytoplasmic domain of Mpl promotes hematopoietic commitment of embryonic stem cells in vitro, and postulated that Mpl could be important in the establishment of definitive hematopoiesis. To answer this question, we investigated the temporal expression of Mpl during mouse development by in situ hybridization. We found Mpl expression in the HSCs clusters emerging in the AGM region, and in the fetal liver (FL) as early as E10.5. Using Mpl(-/-) mice, the functional relevance of Mpl expression was tested by comparing the hematopoietic progenitor (HP) content, long-term hematopoietic reconstitution (LTR) abilities and HSC content of control and Mpl(-/-) embryos at different times of development. In the AGM, we observed delayed production of HSCs endowed with normal LTR but presenting a self-renewal defect. During FL development, we detected a decrease in HP and HSC potential associated with a defect in amplification and self-renewal/survival of the lin(-) AA4.1(+) Sca1(+) population of HSCs. These results underline the dual role of Mpl in the generation and expansion of HSCs during establishment of definitive hematopoiesis.     

FIP200, an essential component of mammalian autophagy is indispensible for fetal hematopoiesis

Autophagy, an evolutionarily conserved cellular process for bulk protein degradation through lysosomes, plays important roles in various physiological and pathological processes. Recent studies suggest that autophagy also participates in erythroid development. However, to what extent autophagy is involved in hematopoiesis is largely unknown. FIP200 (focal adhesion kinase family interacting protein of 200 kD) is a newly identified essential autophagy gene and a component of the ULK-Atg13-FIP200 complex. We show that mice lacking FIP200 in hematopoietic cells (CKO mice) experience perinatal lethality associated with severe erythroblastic anemia. FIP200 is cell-autonomously required for the maintenance and function of fetal hematopoietic stem cells (HSCs). FIP200 deletion in HSCs does not result in increased apoptosis. However, aberrantly increased HSC proliferation and myeloid expansion are found in CKO embryos, which may be responsible for the depletion of fetal HSCs. Consistent with an essential role of FIP200 in autophagy, FIP200-null fetal HSCs as well as other hematopoietic cells exhibit increased mitochondria mass and reactive oxygen species (ROS). Together, our data identify FIP200 as a key intrinsic regulator of fetal HSCs and suggest a role of autophagy in fetal hematopoiesis and the maintenance of fetal HSCs.     

FIP200, an essential component of mammalian autophagy is indispensible for fetal hematopoiesis

Autophagy, an evolutionarily conserved cellular process for bulk protein degradation through lysosomes, plays important roles in various physiological and pathological processes. Recent studies suggest that autophagy also participates in erythroid development. However, to what extent autophagy is involved in hematopoiesis is largely unknown. FIP200 (focal adhesion kinase family interacting protein of 200 kD) is a newly identified essential autophagy gene and a component of the ULK-Atg13-FIP200 complex. We show that mice lacking FIP200 in hematopoietic cells (CKO mice) experience perinatal lethality associated with severe erythroblastic anemia. FIP200 is cell-autonomously required for the maintenance and function of fetal hematopoietic stem cells (HSCs). FIP200 deletion in HSCs does not result in increased apoptosis. However, aberrantly increased HSC proliferation and myeloid expansion are found in CKO embryos, which may be responsible for the depletion of fetal HSCs. Consistent with an essential role of FIP200 in autophagy, FIP200-null fetal HSCs as well as other hematopoietic cells exhibit increased mitochondria mass and reactive oxygen species (ROS). Together, our data identify FIP200 as a key intrinsic regulator of fetal HSCs and suggest a role of autophagy in fetal hematopoiesis and the maintenance of fetal HSCs.     

Rb regulates interactions between hematopoietic stem cells and their bone marrow microenvironment

Hematopoiesis is maintained by stem cells (HSCs) that undergo fate decisions by integrating intrinsic and extrinsic signals, with the latter derived from the bone marrow (BM) microenvironment. Cell-cycle regulation can modulate stem cell fate, but it is unknown whether this represents an intrinsic or extrinsic effector of fate decisions. We have investigated the role of the retinoblastoma protein (RB), a central regulator of the cell cycle, in hematopoiesis. Widespread inactivation of RB in the murine hematopoietic system resulted in profound myeloproliferation. HSCs were lost from the BM due to mobilization to extramedullary sites and differentiation. This phenotype was not intrinsic to HSCs, but, rather, was the consequence of an RB-dependent interaction between myeloid-derived cells and the microenvironment. These findings demonstrate that myeloproliferation may result from perturbed interactions between hematopoietic cells and the niche. Therefore, RB extrinsically regulates HSCs by maintaining the capacity of the BM to support normal hematopoiesis and HSCs.     

造血干细胞发育过程中的信号通路调控

血液系统是维持机体生命活动最重要的系统之一,为机体提供所需的氧气和营养物质,通过物质交换维持内环境的稳态,同时为机体提供免疫防御与保护。血细胞是血液的重要组成成分,机体中成熟血细胞类型起源于具有自我更新及分化潜能的多能成体干细胞—造血干细胞(hematopoietic stem cells,HSCs)。造血干细胞及各类血细胞产生、发育及成熟的过程称为造血过程,该过程开始于胚胎发育早期并贯穿整个生命过程,任一阶段出现异常都可能导致血液疾病的发生。因此,深入探究造血发育过程及其调控机制对于认识并治疗血液疾病至关重要。近年来,以小鼠(Mus musculus)和斑马鱼(Danio rerio)作为动物模型来研究造血发育取得了一系列的进展。其中,BMP、Notch和Wnt等信号通路对造血干细胞的命运决定和产生发挥了重要作用。本文对这些信号通路在小鼠和斑马鱼造血过程中的调控作用进行系统总结,以期能够完善造血发育过程的调控网络并为临床应用提供指导。