Interplay between proliferation and differentiation within the myogenic lineage.

In muscle cells, as in a variety of cell types, proliferation and differentiation are mutually exclusive events controlled by a balance of opposing cellular signals. Members of the MyoD family of muscle-specific helix-loop-helix proteins which, in collaboration with ubiquitous factors, activate muscle differentiation and inhibit cell proliferation function at the nexus of the cellular circuits that control proliferation and differentiation of muscle cells. The activities of these myogenic regulators are negatively regulated by peptide growth factors and activated oncogenes whose products transmit growth signals from the membrane to the nucleus. Recent studies have revealed multiple mechanisms through which intracellular growth factor signals may interfere with the functions of the myogenic regulators. When expressed at high levels, members of the MyoD family can override mitogenic signals and can cause growth arrest independent of their effects on differentiation. The ability of these myogenic regulators to inhibit proliferation of normal as well as transformed cells from multiple lineages suggests that they interact with conserved components of the cellular machinery involved in cell cycle progression and that similar types of regulatory factors participate in differentiation and cell cycle control in diverse cell types.     

Different roles of ERK and p38 MAP kinases during tube formation from endothelial cells cultured in 3-dimensional collagen matrices

In a two-dimensional (2D) culture dish, the major activity of endothelial cells is proliferation with limited morphological change. When cultured in a three-dimensional (3D) collagen gel matrix, endothelial cells undergo a series of morphological changes starting with development of intracellular vacuoles and followed by cell elongation. Adjacent cells then coalesce to form tube-like structures. This process mimics the steps of capillary formation during angiogenesis. Using this model, we investigated the roles of extracellular signal-regulated kinase (ERK) and p38 MAP kinase (p38) in the tube formation from human umbilical vein endothelial cells (HUVEC). Proliferating HUVEC gradually lost their ability to divide after being transferred to 3D collagen matrices, where differentiation became the dominant cellular activity. The transition from proliferation to the differentiation state was accompanied by a drastic reduction of cyclin-dependent kinases CDC2, CDK4, and retinoblastoma (Rb) protein, but the expression of cyclin-dependent kinase inhibitor, p27kip1, was increased. Inhibition of p38 by SB203580 partially prevented these changes and increased the proliferation rate of HUVEC. However, cells under this condition exhibited unusually elongated cell bodies, and they were unable to coalesce to form tube structures. Inhibition of ERK neither affected the cell proliferation rate nor the expression levels of cell cycle regulators, but it completely blocked tube formation by inducing apoptosis, a finding different from the best-known role of ERK in cell proliferation in the 2D cell culture systems. We conclude that the major function of ERK is to maintain cell viability while p38 plays multiple roles in controlling cell proliferation, viability, and morphogenesis during tube formation.     

Cell cycle genes in chondrocyte proliferation and differentiation.

Coordinated proliferation and differentiation of growth plate chondrocytes controls longitudinal growth of endochondral bones. While many extracellular factors regulating these processes have been identified, much less is known about the intracellular mechanisms transducing and integrating these extracellular signals. Recent evidence suggests that cell cycle proteins play an important role in the coordination of chondrocyte proliferation and differentiation. Our current knowledge of the function and regulation of cell cycle proteins in endochondral ossification is summarized.     

Sequential activation of Notch family receptors during mouse spermatogenesis

The expression pattern of Notch family receptors during mouse spermatogenesis was examined by immunohistochemistry. The entire cytoplasm of spermatogonia, spermatocytes and spermatids showed staining with antibodies against extracellular domains of Notch1, 2 and 4. In contrast, the nuclei of spermatogonia showed staining with an antibody against the intracellular domain of Notch3, and the nuclei of spermatocytes and spermatids showed staining with antibodies against the intracellular domains of Notch1 and 4. During regeneration of spermatogonia in busulfan-treated mice, the nuclei of all proliferating cells showed staining for the intracellular domain of Notch3. Western blot analysis showed that the molecular weights of the intracellular domains of Notch1 and 3 localizing in the nuclear fraction were smaller than those in the cytoplasmic fraction. This was consistent with the theory that the intracellular domain of Notch was cleaved in the cytoplasm and translocated to the nucleus. These results suggest that different Notch signals are sequentially activated during mouse spermatogenesis and control the proliferation and differentiation of spermatogenic stem cells.     

Cyclin D1 localizes in the cytoplasm of keratinocytes during skin differentiation and regulates cell–matrix adhesion

The function of Cyclin D1 (CycD1) has been widely studied in the cell nucleus as a regulatory subunit of the cyclin-dependent kinases Cdk4/6 involved in the control of proliferation and development in mammals. CycD1 has been also localized in the cytoplasm, where its function nevertheless is poorly characterized. In this work we have observed that in normal skin as well as in primary cultures of human keratinocytes, cytoplasmic localization of CycD1 correlated with the degree of differentiation of the keratinocyte. In these conditions, CycD1 co-localized in cytoplasmic foci with exocyst components (Sec6) and regulators (RalA), and with β1 integrin, suggesting a role for CycD1 in the regulation of keratinocyte adhesion during differentiation. Consistent with this hypothesis, CycD1 overexpression increased β1 integrin recycling and drastically reduced the ability of keratinocytes to adhere to the extracellular matrix. We propose that localization of CycD1 in the cytoplasm during skin differentiation could be related to the changes in detachment ability of keratinocytes committed to differentiation.     

FoxO转录因子的活性调节及对哺乳动物细胞进程的调控

FoxO转录因子在哺乳动物的细胞分化、增殖和细胞存活中发挥着重要调控作用,其转录活性受PI3K通路、非PI3K依赖通路、乙酰化和泛素化作用等多种途径调控.FoxO受到上游信号分子PI3K/Akt、SGK等的激活,调节靶基因的转录,从而调节哺乳动物细胞周期的进程和凋亡事件.FoxO已成为肿瘤、癌症科学研究的热点之一.     

The tail of integrin activation

Integrins are essential adhesion receptors found on the surfaces of all metazoan cells. As regulators of cell migration and extracellular matrix assembly, these membrane-spanning heterodimers are critical for embryonic development, tissue repair and immune responses. Signals transmitted by integrins from outside to inside the cell promote cell survival and proliferation, but integrin affinity for extracellular ligands can also be controlled by intracellular cues. This bidirectional signaling is mediated by the short cytoplasmic tails of the two integrin subunits. Recent structural and functional studies of various integrin fragments and complexes between the cytoplasmic tails and intracellular proteins, such as talin, have provided new insight into the signaling processes centered around the tails, particularly inside-out integrin activation.     

Regulatory mechanisms and function of ERK MAP kinases

Spatiotemporal control of the Ras/ERK MAP kinase signaling pathway is a key factor for determining the specificity of cellular responses including cell proliferation, cell differentiation and cell survival. The fidelity of this signaling is regulated by docking interactions as well as scaffolding. Subcellular localization of ERK is controlled by cytoplasmic ERK anchoring proteins that have a nuclear export signal (NES), such as MEK. In quiescent cells, ERK and MEK localize to the cytoplasm. In response to stimulation, dissociation of the MEK-ERK complex is induced and activated ERK translocates to the nucleus. Recently, several negative regulators for Ras/ERK signaling have been identified and their detailed molecular mechanisms have been analyzed. Among them, Sprouty and Sef act as a temporal and a spatial regulator, respectively, for Ras/ERK signaling. Thus, multiple factors are involved in control of Ras/ERK signaling.     

The SHP—2 tyrosine phosphatase：Signaling mechanisms and biological functions

Cellular biological avtivities are tightly controlled by intracellular signaling processes initiated by extracellular signals.Protein tyrosine phosphatases,which remove phosphate groups from phosphorylated signaling molecules,play equally important tyrosine roles as protein tyrosine kinases in signal transduction.SHP-2 a cytoplasmic SH2 domain containing protein tyrosine phosphatase,is involved in the signaling pathways of a variety of growth factors and cytokines.Recent studies have clearly demonstrated that this phosphatase plays an important role in transducing signal relay from the cell surface to the nucleus,and is a critical intracellular regulator in mediating cell proliferation and differentiation.     

神经干细胞体外增殖分化的钙成像研究

神经干细胞具有广阔的应用前景,但对于其增殖和分化的内源机制、外部环境信号还并不十分了解。研究表明,钙信号很可能在其中起到了调控作用。利用钙离子成像技术,观察神经干细胞的单细胞体外增殖和分化过程,记录了在细胞分裂过程中钙信号变化的曲线。发现细胞增殖和分化过程中都会产生钙浓度的变化,但在细胞分裂后期两者钙信号的模式却存在差别。实验结果提示,胞内钙水平的波动只是细胞增殖的伴随产物,但却是细胞分化的必要条件。由此提出钙信号对神经干细胞分化调控机制的假设,并指出其对今后研究的意义。     

Purinergic signaling regulates neural progenitor cell expansion and neurogenesis

Neural stem and progenitor cells typically exhibit a density-dependent survival and expansion, such that critical densities are required below which clonogenic progenitors are lost. This suggests that short-range autocrine factors may be critical for progenitor cell maintenance. We report here that purines drive the expansion of ventricular zone neural stem and progenitor cells, and that purine receptor activation is required for progenitor cells to be maintained as such. Neural progenitors expressed P2Y purinergic receptors and mobilized intracellular calcium in response to agonist. Receptor antagonists suppressed proliferation and permitted differentiation into neurons and glia in vitro, while subsequent removal of purinergic inhibition restored progenitor cell expansion. Real-time bioluminescence imaging of extracellular ATP revealed that the source of extracellular nucleotides are the progenitor cells themselves, which appear to release ATP in episodic burst events. Enzyme histochemistry of the adult rat brain for ectonucleotidase activity revealed that NTDPase, which acts to degrade active ATP and thereby clears it from areas of active purinergic transmission, was selectively localized to the subventricular zone and the dentate gyrus, regions in which neuronal differentiation proceeds from the progenitor cell pool. These data suggest that purine nucleotides act as proliferation signals for neural progenitor cells, and thereby serve as negative regulators of terminal neuronal differentiation. As a result, progenitor cell-derived neurogenesis is thus associated with regions of both active purinergic signaling and modulation thereof.     

Aberrant endosperm development in interploidy crosses reveals a timer of differentiation

The common assumption that the seed failure in interploidy crosses of flowering plants is due to parental genomic imprinting is based on vague interpretations and needs reevaluation since the general question is involved, how differentiation is timed so that cell progenies, while specializing, pass through proper numbers of amplification divisions before proliferation ceases. As recently confirmed, endosperm differentiation is accelerated or de-accelerated, depending upon whether polyploid females are crossed with diploid males, or vice-versa. Unlike the zygote, the first cell of the endosperm is determined to produce a tissue that successively induces growth of maternal tissues, stimulates and nourishes the embryo, and finally ceases cell cycling. Altered timing of endosperm differentiation, thus, perturbs seed development. During fertilization, only the female genomes contribute cytoplasmic equivalents to endosperm development so that in interploidy crosses, the initial amount of cytoplasm per chromosome set is altered, and due to semi-autonomy of cytoplasmic growth, altered numbers of division cycles are needed to provide the amount of cytoplasmic organelles required for differentiation. Cytoplasmic semi-autonomy and dependence of differentiation on an increase in cytoplasm has been shown in other tissues of plants and animals, thus, revealing a common mechanism for intracellular timing of differentiation. As demonstrated, imprinted genes can alter the extent of cell proliferation by interfering with this mechanism.     

Inactivation of the polycomb group protein Ring1B unveils an antiproliferative role in hematopoietic cell expansion and cooperation with tumorigenesis associated with Ink4a deletion

Polycomb group (PcG) proteins act as positive regulators of cell proliferation. Ring1B is a PcG gene essential for embryonic development, but its contribution to cell turnover in regenerating tissues in not known. Here, we have generated a conditional mouse mutant line to study the Ring1B role in adult hematopoiesis. Mutant mice developed a hypocellular bone marrow that paradoxically contained an enlarged, hyperproliferating compartment of immature cells, with an intact differentiation potential. These alterations were associated with differential upregulation of cyclin D2, which occurred in all mutant bone marrow cells, and of p16^Ink4a, observed only in the differentiated compartment. Concurrent inactivation of Ink4a rescued the defective proliferation of maturing cells but did not affect the hyperproliferative activity of progenitors and resulted in a shortening of the onset of lymphomas induced by Ink4a inactivation. These data show that Ring1B restricts the progenitors' proliferation and promotes the proliferation of their maturing progeny by selectively altering the expression pattern of cell cycle regulators along hematopoietic differentiation. The novel antiproliferative role of Ring1B's downregulation of a cell cycle activator may play an important role in the tight control of hematopoietic cell turnover.     

A cell-intrinsic timer that operates during oligodendrocyte development

Multicellular organisms develop on a predictable schedule that depends on both cell-intrinsic timers and sequential cell-cell interactions mediated by extracellular signals. The interplay between intracellular timers and extracellular signals is well illustrated by the development of oligodendrocytes, the cells that make the myelin in the vertebrate central nervous system. An intrinsic timing mechanism operates in each oligodendrocyte precursor cell to limit the length of time the cell divides before terminally differentiating. This mechanism consists of two components, a timing component, which depends on the mitogen platelet-derived growth factor (PDGF) and measures elapsed time, and an effector component, which depends on thyroid hormone and stops cell division and initiates differentiation at the appropriate time. The cell-cycle inhibitor p27/Kip1 accumulates in the precursor cells as they proliferate and is part of both components of the timer. It seems likely that similar timing mechanisms operate in other cell lineages. BioEssays 22:64-71, 2000.     

Fibroblast growth factor 2 and protein kinase C alpha are involved in syndecan-4 cytoplasmic domain modulation of turkey myogenic satellite cell proliferation

Syndecan-4 core protein is composed of extracellular, transmembrane, and cytoplasmic domains. The cytoplasmic domain functions in transmitting signals into the cell through the protein kinase C alpha (PKCα) pathway. The glycosaminoglycan (GAG) and N-linked glycosylated (N-glycosylated) chains attached to the extracellular domain influence cell proliferation. The current study investigated the function of syndecan-4 cytoplasmic domain in combination with GAG and N-glycosylated chains in turkey muscle cell proliferation, differentiation, fibroblast growth factor 2 (FGF2) responsiveness, and PKCα membrane localization. Syndecan-4 or syndecan-4 without the cytoplasmic domain and with or without the GAG and N-glycosylated chains were transfected or co-transfected with a small interfering RNA targeting syndecan-4 cytoplasmic domain into turkey muscle satellite cells. The overexpression of syndecan-4 mutants increased cell proliferation but did not change differentiation. Syndecan-4 mutants had increased cellular responsiveness to FGF2 during proliferation. Syndecan-4 increased PKCα cell membrane localization, whereas the syndecan-4 mutants decreased PKCα cell membrane localization compared to syndecan-4. However, compared to the cells without transfection, syndecan-4 mutants increased cell membrane localization of PKCα. These data indicated that the syndecan‐4 cytoplasmic domain and the GAG and N-glycosylated chains are critical in syndecan-4 regulating satellite cell proliferation, responsiveness to FGF2, and PKCα cell membrane localization.     

Integrin-linked kinase (ILK) and its interactors: a new paradigm for the coupling of extracellular matrix to actin cytoskeleton and signaling complexes.

How intracellular cytoskeletal and signaling proteins connect and communicate with the extracellular matrix (ECM) is a fundamental question in cell biology. Recent biochemical, cell biological, and genetic studies have revealed important roles of cytoplasmic integrin-linked kinase (ILK) and its interactive proteins in these processes. Cell adhesion to ECM is an important process that controls cell shape change, migration, proliferation, survival, and differentiation. Upon adhesion to ECM, integrins and a selective group of cytoskeletal and signaling proteins are recruited to cell matrix contact sites where they link the actin cytoskeleton to the ECM and mediate signal transduction between the intracellular and extracellular compartments. In this review, we discuss the molecular activities and cellular functions of ILK, a protein that is emerging as a key component of the cell-ECM adhesion structures.