Human Haematopoiesis in Steady State and Following Intense Perturbations

Shochat, Eliezer; Stemmer, Salomon M.; Segel, Lee A.

doi:10.1006/bulm.2002.0305

Cited by 31 publications

(32 citation statements)

References 49 publications

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“…doi:10.1371/journal.pcbi.0030053.g004 stimulation and the microenvironment within the SC niche together impose differentiation on one or both daughter cells that result from an SC division. However, the tendency of SCs to self-renew will ensure that if the SC pool is depleted (e.g., with high-dose chemotherapy), the remaining SCs can expand to occupy the available niches [40].…”

Section: Discussionmentioning

confidence: 99%

(A)Symmetric Stem Cell Replication and Cancer

Dingli¹,

Traulsen²,

michor³

2005

PLoS Comput Biol

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Most tissues in metazoans undergo continuous turnover due to cell death or epithelial shedding. Since cellular replication is associated with an inherent risk of mutagenesis, tissues are maintained by a small group of stem cells (SCs) that replicate slowly to maintain their own population and that give rise to differentiated cells. There is increasing evidence that many tumors are also maintained by a small population of cancer stem cells that may arise by mutations from normal SCs. SC replication can be either symmetric or asymmetric. The former can lead to expansion of the SC pool. We describe a simple model to evaluate the impact of (a)symmetric SC replication on the expansion of mutant SCs and to show that mutations that increase the probability of asymmetric replication can lead to rapid mutant SC expansion in the absence of a selective fitness advantage. Mutations in several genes can lead to this process and may be at the root of the carcinogenic process.

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Section: Discussionmentioning

confidence: 99%

(A)Symmetric Stem Cell Replication and Cancer

Dingli¹,

Traulsen²,

michor³

2005

PLoS Comput Biol

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“…Indeed, numerous mathematical models of the neutrophil production-also termed granulopoiesis-have been suggested over the years (Rubinow and Lebowitz, 1975;Lajtha et al, 1962;King-Smith and Morley, 1970;Blumenson and Bross, 1979;Abkowitz et al, 1996;Bernard et al, 2003;Zamboni et al, 2001;Krzyzanski et al, 1999;Shochat and Stemmer, 2002;Ostby et al, 2003;Scholz et al, 2005;Vainstein et al, 2005;Panetta et al, 2003;Wang et al, 2001;Foley et al, 2006;Haurie et al, 2000). Each of the models showed a good agreement with some empirical data.…”

Section: Introductionmentioning

confidence: 99%

“…Each of the models showed a good agreement with some empirical data. A number of these models were specifically developed to mathematically capture the detailed biology of the bone marrow (Rubinow and Lebowitz, 1975;Blumenson and Bross, 1979;Abkowitz et al, 1996;Shochat and Stemmer, 2002;Vainstein et al, 2005). Such models are intrinsically high dimensional, nonlinear and often contain large parameter sets.…”

Section: Introductionmentioning

confidence: 99%

G-CSF Control of Neutrophils Dynamics in the Blood

2007

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White blood cell neutrophil is a key component in the fast initial immune response against bacterial and fungal infections. Granulocyte colony stimulating factor (G-CSF) which is naturally produced in the body, is known to control the neutrophils production in the bone marrow and the neutrophils delivery into the blood. In oncological practice, G-CSF injections are widely used to treat neutropenia (dangerously low levels of neutrophils in the blood) and to prevent the infectious complications that often follow chemotherapy. However, the accurate dynamics of G-CSF neutrophil interaction has not been fully determined and no general scheme exists for an optimal G-CSF application in neutropenia. Here we develop a two-dimensional ordinary differential equation model for the G-CSF-neutrophil dynamics in the blood. The model is built axiomatically by first formally defining from the biology the expected properties of the model, and then deducing the dynamic behavior of the resulting system. The resulting model is structurally stable, and its dynamical features are independent of the precise form of the various rate functions. Choosing a specific form for these functions, three complementary parameter estimation procedures for one clinical (training) data set are utilized. The fully parameterized model (6 parameters) provides adequate predictions for several additional clinical data sets on time scales of several days. We briefly discuss the utility of this relatively simple and robust model in several clinical conditions.

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“…There are approximately $1.0 Â 10 5 CFU-GEMM cells [30] and significantly more CFU-GM cells ($10 8 ). We estimate that each CFU-GEMM may contribute to hematopoiesis for an average of $60 days (range 40-340 days), and that it replicates at an average rate of once every 50 days (range 35-285 days), while the replication rate of CFU-GM is significantly faster [21].…”

Section: Normal Mutation Rate -Still Many Mutationsmentioning

confidence: 98%

Somatic mutations and the hierarchy of hematopoiesis

et al. 2010

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Clonal disease is often regarded as almost synonymous with cancer. However, it is becoming increasingly clear that our bodies harbor numerous mutant clones that are not tumors, and mostly give rise to no disease at all. Here we discuss three somatic mutations arising within the hematopoietic system: BCR-ABL, characteristic of chronic myeloid leukemia; mutations of the PIG-A gene, characteristic of paroxysmal nocturnal hemoglobinuria; the V617F mutation in the JAK2 gene, characteristic of myeloproliferative diseases. The population frequencies of these three blood disorders fit well with a hierarchical model of hematopoiesis. The fate of any mutant clone will depend on the target cell and on the fitness advantage, if any, that the mutation confers on the cell. In general, we can expect that only a mutation in a hematopoietic stem cell will give long-term disease; the same mutation taking place in a cell located more downstream may produce just a ripple in the hematopoietic ocean.

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Human Haematopoiesis in Steady State and Following Intense Perturbations

Cited by 31 publications

References 49 publications

(A)Symmetric Stem Cell Replication and Cancer

(A)Symmetric Stem Cell Replication and Cancer

G-CSF Control of Neutrophils Dynamics in the Blood

Somatic mutations and the hierarchy of hematopoiesis

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