Determinative properties of muscle lineages in ascidian embryos

Blastomeres removed from early cleavage stage ascidian embryos and reared to 'maturity' as partial embryos often elaborate tissue-specific features typical of their constituent cell lineages. We used this property to study recent corrections of the ascidian larval muscle lineage and to compare the ways in which different lineages give rise to muscle. Our evaluation of muscle differentiation was based on histochemical localization and quantitative radiometric measurement of a muscle-specific acetylcholinesterase activity, and the development of myofilaments and myofibrils as observed by electron microscopy. Although the posterior-vegetal blastomeres (B4.1 pair) of the 8-cell embryo have long been believed to be the sole precursors of larval muscle, recent studies using horseradish peroxidase to mark cell lineages have shown that small numbers of muscle cells originate from the anterior-vegetal (A4.1) and posterior-animal (b4.2) blastomeres of this stage. Fully differentiated muscle expression in isolated partial embryos of A4.1-derived cells requires an association with cells from other lineages whereas muscle from B4.1 blastomeres develops autonomously. Clear differences also occurred in the time acetylcholinesterase activity was first detected in partial embryos from these two sources. Isolated b4.2 cells failed to show any muscle development even in combination with anterior-animal cells (a4.2) and are presumably even more dependent on normal cell interactions and associations. Others have noted an additional distinction between the different sources of muscle: muscle cells from non-B4.1 lineages occur exclusively in the distal part of the tail, while the B4.1 descendants contribute those cells in the proximal and middle regions. During the course of ascidian larval evolution tail muscle probably had two origins: the primary lineage (B4.1) whose fate was set rigidly at early cleavage stages and secondarily evolved lineages which arose later by recruitment of cells from other tissues resulting in increased tail length. In contrast to the B4.1 lineage, muscle development in the secondary lineages is controlled less rigidly by processes that depend on cell interactions.     

Patterns of cell division and the risk of cancer

Epidermal and intestinal tissues divide throughout life to replace lost surface cells. These renewing tissues have long-lived basal stem cell lineages that divide many times, each division producing one stem cell and one transit cell. The transit cell divides a limited number of times, producing cells that move up from the basal layer and eventually slough off from the surface. If mutation rates are the same in stem and transit divisions, we show that minimal cancer risk is obtained by using the fewest possible stem divisions subject to the constraints imposed by the need to renew the tissue. In this case, stem cells are a necessary risk imposed by the constraints of tissue architecture. Cairns suggested that stem cells may have lower mutation rates than transit cells do. We develop a mathematical model to study the consequences of different stem and transit mutation rates. Our model shows that stem cell mutation rates two or three orders of magnitude less than transit mutation rates may favor relatively more stem divisions and fewer transit divisions, perhaps explaining how renewing tissues allocate cell divisions between long stem and short transit lineages.     

Recruitment of healthy mitochondria fuels transmissible cancers

The replication of mitochondrial DNA (mtDNA) is not under strict control of the nucleus. Therefore, within-cell selection can favour mtDNA variants with a replication or survival advantage even if deleterious for the cell. Here, we consider how the balance between selection within and among cells is shifted in cancer cell lineages, and how this affects the somatic evolution of mitochondria. Cancer cell lineages are known to be prone to mitochondrial genetic erosion. Nevertheless, some cancer lineages are long lived and a few exceptional lineages even can survive their host because of horizontal transmission to other individuals. Recent work now shows that such transmissible cancer cell lineages occasionally secondarily recruit the mitochondrial genome of their host, which we propose as a means to replace genetically eroded mitochondrial genomes. Studying the dynamics of the horizontal exchange of mtDNA between somatic cells may provide important insight into the evolution of mitochondria during somatic growth and in mitochondrial diseases.     

Epigenetic regulation in adult stem cells and cancers

Adult stem cells maintain tissue homeostasis by their ability to both self-renew and differentiate to distinct cell types. Multiple signaling pathways have been shown to play essential roles as extrinsic cues in maintaining adult stem cell identity and activity. Recent studies also show dynamic regulation by epigenetic mechanisms as intrinsic factors in multiple adult stem cell lineages. Emerging evidence demonstrates intimate crosstalk between these two mechanisms. Misregulation of adult stem cell activity could lead to tumorigenesis, and it has been proposed that cancer stem cells may be responsible for tumor growth and metastasis. However, it is unclear whether cancer stem cells share commonalities with normal adult stem cells. In this review, we will focus on recent discoveries of epigenetic regulation in multiple adult stem cell lineages. We will also discuss how epigenetic mechanisms regulate cancer stem cell activity and probe the common and different features between cancer stem cells and normal adult stem cells.     

The BTB-ZF family of transcription factors: key regulators of lineage commitment and effector function development in the immune system

Successful immunity depends upon the activity of multiple cell types. Commitment of pluripotent precursor cells to specific lineages, such as T or B cells, is obviously fundamental to this process. However, it is also becoming clear that continued differentiation and specialization of lymphoid cells is equally important for immune system integrity. Several members of the BTB-ZF family have emerged as critical factors that control development of specific lineages and also of specific effector subsets within these lineages. For example, BTB-ZF genes have been shown to control T cell versus B cell commitment and CD4 versus CD8 lineage commitment. Others, such as PLZF for NKT cells and Bcl-6 for T follicular helper cells, are necessary for the acquisition of effector functions. In this review, we summarize current findings concerning the BTB-ZF family members with a reported role in the immune system.     

Characterization of human mesenchymal stem cell secretome at early steps of adipocyte and osteoblast differentiation

Background  

It is well established that adipose tissue plays a key role in energy storage and release but is also a secretory organ and a source of stem cells. Among different lineages, stem cells are able to differentiate into adipocytes and osteoblasts. As secreted proteins could regulate the balance between both lineages, we aimed at characterizing the secretome of human multipotent adipose-derived stem cell (hMADS) at an early step of commitment to adipocytes and osteoblasts.     

Low Immunogenicity of Neural Progenitor Cells Differentiated from Induced Pluripotent Stem Cells Derived from Less Immunogenic Somatic Cells

The groundbreaking discovery of induced pluripotent stem cells (iPS cells) provides a new source for cell therapy. However, whether the iPS derived functional lineages from different cell origins have different immunogenicity remains unknown. It had been known that the cells isolated from extra-embryonic tissues, such as umbilical cord mesenchymal cells (UMCs), are less immunogenic than other adult lineages such as skin fibroblasts (SFs). In this report, we differentiated iPS cells from human UMCs and SFs into neural progenitor cells (NPCs) and analyzed their immunogenicity. Through co-culture with allologous peripheral blood mononuclear cells (PBMCs), we showed that UMCs were indeed less immunogenic than skin cells to simulate proliferation of PBMCs. Surprisingly, we found that the NPCs differentiated from UMC-iPS cells retained low immunogenicity as the parental UMCs based on the PBMC proliferation assay. In cytotoxic expression assay, reactions in most kinds of immune effector cells showed more perforin and granzyme B expression with SF-NPCs stimulation than that with UMC-NPCs stimulation in PBMC co-culture system, in T cell co-culture system as well. Furthermore, through whole genome expression microarray analysis, we showed that over 70 immune genes, including all members of HLA-I, were expressed at lower levels in NPCs derived from UMC-iPS cells than that from SF-iPS cells. Our results demonstrated a phenomenon that the low immunogenicity of the less immunogenic cells could be retained after cell reprogramming and further differentiation, thus provide a new concept to generate functional lineages with lower immunogenicity for regenerative medicine.     

The common myelolymphoid progenitor: a key intermediate stage in hemopoiesis generating T and B cells

We have previously shown that the common progenitors for myeloid, T, and B cell lineages are enriched in the earliest population of murine fetal liver. However, it remained unclear whether such multipotent progenitors represent the pluripotent progenitors capable of generating all hemopoietic cells or they also comprise progenitors restricted to myeloid, T, and B cell lineages. To address this issue, we have developed a new clonal assay covering myeloid, erythroid, T, and B cell lineages, and using this assay the developmental potential of individual cells in subpopulations of lineage marker-negative (Lin(-)) c-kit(+) murine fetal liver cells was investigated. We identified the progenitor generating myeloid, T, and B cells, but not erythroid cells in the Sca-1(high) subpopulation of Lin(-)c-kit(+) cells that can thus be designated as the common myelolymphoid progenitor (CMLP). Common myeloerythroid progenitors were also detected. These findings strongly suggest that the first branching point in fetal hemopoiesis is between the CMLP and common myeloerythroid progenitors. T and B cell progenitors may be derived from the CMLP through the previously identified myeloid/T and myeloid/B bipotent stages, respectively.     

Clonal analysis of the cell lineages in the male flower of maize

The cell lineages in the male flower of maize were characterized using X-rays and transposable elements to produce clonal sectors differing in anthocyanin pigmentation. Less than 50% of the somatic tassel mutations (caused by reversion of unstable color mutations) that were visible on the anther wall were sexually transmitted by the male gametes, unless the sectors were larger than half the tassel circumference. This result is explained by showing that: (a) both the outer (LI) and inner (LII) lineages of the shoot apical meristem form a cell layer in the bilayered anther wall, and that anther pigmentation can be derived from either cell layer; and that (b) the male germ cells are derived almost exclusively from the LII. Therefore, while reversion events in either the LI or LII are visible on the anther, only the LII events are heritable. Reversion events that occur prior to the organization of the shoot apical meristem however, produce large (usually more than one-half tassel) sectors that include both the outer and inner lineages. In contrast to the high level of cell layer invasion previously reported during leaf development, during anther development less than 10(-3) cells in the LI invade the LII to form male gametes. The strong correlation between cell lineage and cell fate in the maize anther has implications for studies on plant evolution and the genetic improvement of cereals by DNA transformation.     

Neurogenin 3 and the enteroendocrine cell lineage in the adult mouse small intestinal epithelium

It is thought that small intestinal epithelial stem cell progeny, via Notch signaling, yield a Hes1-expressing columnar lineage progenitor and an Atoh1 (also known as Math1)-expressing common progenitor for all granulocytic lineages including enteroendocrine cells, one of the body's largest populations of endocrine cells. Because Neurogenin 3 (Neurog3) null mice lack enteroendocrine cells, Neurog3-expressing progenitors derived from the common granulocytic progenitor are thought to produce the enteroendocrine lineage, although more recent work indicates that Neurog3+ progenitors also contribute to non-enteroendocrine lineages. We aimed to test this model and better characterize the progenitors leading from the stem cells to the enteroendocrine lineage. We investigated clones derived from enteroendocrine precursors and found no evidence of a common granulocytic progenitor that routinely yields all granulocytic lineages. Rather, enteroendocrine cells are derived from a short-lived bipotential progenitor whose offspring, probably via Notch signaling, yield a Neurog3+ cell committed to the enteroendocrine lineage and a progenitor committed to the columnar lineage. The Neurog3+ cell population is heterogeneous; only about 1/3 are slowly cycling progenitors, the rest are postmitotic cells in early stages of enteroendocrine differentiation. No evidence was found that Neurog3+ cells contribute to non-enteroendocrine lineages. Revised lineage models for the small intestinal epithelium are introduced.     

Stochastic Dynamics of Interacting Haematopoietic Stem Cell Niche Lineages

Since we still know very little about stem cells in their natural environment, it is useful to explore their dynamics through modelling and simulation, as well as experimentally. Most models of stem cell systems are based on deterministic differential equations that ignore the natural heterogeneity of stem cell populations. This is not appropriate at the level of individual cells and niches, when randomness is more likely to affect dynamics. In this paper, we introduce a fast stochastic method for simulating a metapopulation of stem cell niche lineages, that is, many sub-populations that together form a heterogeneous metapopulation, over time. By selecting the common limiting timestep, our method ensures that the entire metapopulation is simulated synchronously. This is important, as it allows us to introduce interactions between separate niche lineages, which would otherwise be impossible. We expand our method to enable the coupling of many lineages into niche groups, where differentiated cells are pooled within each niche group. Using this method, we explore the dynamics of the haematopoietic system from a demand control system perspective. We find that coupling together niche lineages allows the organism to regulate blood cell numbers as closely as possible to the homeostatic optimum. Furthermore, coupled lineages respond better than uncoupled ones to random perturbations, here the loss of some myeloid cells. This could imply that it is advantageous for an organism to connect together its niche lineages into groups. Our results suggest that a potential fruitful empirical direction will be to understand how stem cell descendants communicate with the niche and how cancer may arise as a result of a failure of such communication.     

Stem cells are units of natural selection in a colonial ascidian

Stem cells are highly conserved biological units of development and regeneration. Here we formally demonstrate that stem cell lineages are also legitimate units of natural selection. In a colonial ascidian, Botryllus schlosseri, vascular fusion between genetically distinct individuals results in cellular parasitism of somatic tissues, gametes, or both. We show that genetic hierarchies of somatic and gametic parasitism following fusion can be replicated by transplanting cells between colonies. We prospectively isolate a population of multipotent, self-renewing stem cells that retain their competitive phenotype upon transplantation. Their single-cell contribution to either somatic or germline fates, but not to both, is consistent with separate lineages of somatic and germline stem cells or pluripotent stem cells that differentiate according to the niche in which they land. Since fusion is restricted to individuals that share a fusion/histocompatibility allele, these data suggest that histocompatibility genes in Botryllus evolved to protect the body from parasitic stem cells usurping asexual or sexual inheritance.     

Polymorphism and evolution of vulval precursor cell lineages within two nematode genera, Caenorhabditis and Oscheius

BACKGROUND: The cell lineage of nematodes is mostly invariant for a given species, but varies between species. One can thus wonder how a cell lineage varies during evolution. We have started a microevolutionary approach within two genera by observing lineage variations of vulval precursor cells in different natural nematode populations of the same and closely related species. RESULTS: In Caenorhabditis elegans, the P3.p cell lineage is variable within a genetically homogeneous population and polymorphic between wild strains. Irrespective of its division pattern, P3.p is competent to form vulval tissue in different C. elegans strains, whereas it is not competent in C. briggsae. In Oscheius sp. 1, P4.p and P8.p lineages are strongly polymorphic. Within each genus, these intraspecies polymorphisms in cell lineages are amplified between closely related species. In Oscheius sp. 1, the large polymorphisms in P4.p and P8.p lineages allowed us to undertake a genetic analysis of the variation between two pairs of strains. Multiple loci are involved in cell lineage differences, and variation at one locus appears to have a relatively strong effect. In addition to these large lineage variations in cells that do not normally contribute to the vulva, we find minor variations (errors) in vulval lineages, which represent the precision level of the vulval-patterning process and point to a selection pressure for maintenance of a large vulval equivalence group. CONCLUSIONS: Polymorphisms in vulval cell lineage are found within a given nematode species, and could be instrumental in explaining evolutionary variations between closely related species.     

肌源干细胞可塑性研究进展

目前已证实肌肉中至少存在两种干细胞:肌卫星细胞和肌源干细胞。肌源干细胞被认为是卫星细胞的前体细胞,具有较高的增殖能力、更好的细胞生存能力和更宽的分化能力。肌源干细胞不仅能够分化成血、肌肉、脂肪、骨、软骨、内皮等中胚层细胞,而且也能打破胚层限制分化成外胚层和内胚层细胞。文章对肌源干细胞的分离纯化、鉴定、可塑性及临床应用做一综述。     

Postembryonic nongonadal cell lineages of the nematode Panagrellus redivivus: Description and comparison with those of Caenorhabditis elegans

The postembryonic nongonadal cell lineages of the nematode Panagrellus redivivus are described and compared with those of Caenorhabditis elegans. The newly hatched larvae of P. redivivus females and males and C. elegans hermaphrodites and males are very similar. An almost identical set of blast cells divides postembryonically in P. redivivus and C. elegans to produce similar changes in the neuronal, muscular, hypodermal, and digestive systems. Most of these cell lineages are invariant; however, there is substantial variability in the number of cell divisions in the relatively extensive lineages of the lateral hypodermis of P. redivivus. Typically, in P. redivivus females, 55 blast cells generate 635 surviving progeny and 29 cell deaths; in P. redivivus males, 59 blast cells generate 758 surviving progeny and 35 cell deaths. The lineages generating the cells of the male tails of P. redivivus and C. elegans are almost identical; thus, the grossly different characteristics of these structures must reflect differences in the morphogenesis of cells equivalent in lineage history. Laser ablation experiments demonstrate that the gonad induces vulva development and that cell-cell interactions are important in specifying the fates of hypodermal precursor cells. The lateral hypodermal lineages provide striking examples of the apparent construction of complex lineages from modular sublineages; one simple pattern of cell divisions and cell fates occurs 70 times in the P. redivivus female. The differences in cell lineage between P. redivivus and C. elegans are relatively minor, and many appear to have involved two types of evolutionary change: the replacement of sublineages, and the modification of sublineages by the four classes of lineage transformations previously proposed based on a comparison of P. redivivus and C. elegans gonadal cell lineages (Sternberg and Horvitz, 1981). These types of differences suggest that the genetic programming of cell lineage includes instructions specifying where and when a particular sublineage is utilized, and other instructions specifying the nature of that sublineage.