Maria A. Ciemerych

Cyclins D2 and D1 Are Essential for Postnatal Pancreatic β-Cell Growth

ABSTRACT Regulation of adult β-cell mass in pancreatic islets is essential to preserve sufficient insulin secretion in order to appropriately regulate glucose homeostasis. In many tissues mitogens influence development by stimulating D-type cyclins (D1, D2, or D3) and activating cyclin-dependent kinases (CDK4 or CDK6), which results in progression through the G1 phase of the cell cycle. Here we show that cyclins D2 and D1 are essential for normal postnatal islet growth. In adult murine islets basal cyclin D2 mRNA expression was easily detected, while cyclin D1 was expressed at lower levels and cyclin D3 was nearly undetectable. Prenatal islet development occurred normally in cyclin D2− / − or cyclin D1 +/ − D2 − / − mice. However, β-cell proliferation, adult mass, and glucose tolerance were decreased in adult cyclin D2 − / − mice, causing glucose intolerance that progressed to diabetes by 12 months of age. Although cyclin D1 +/ − mice never developed diabetes, life-threatening diabetes developed in 3-month-old cyclin D1 − /+ D2 − / − mice as β-cell mass decreased after birth. Thus, cyclins D2 and D1 were essential for β-cell expansion in adult mice. Strategies to tightly regulate D-type cyclin activity in β cells could prevent or cure diabetes.

The critical role of cyclin D2 in adult neurogenesis

Adult neurogenesis (i.e., proliferation and differentiation of neuronal precursors in the adult brain) is responsible for adding new neurons in the dentate gyrus of the hippocampus and in the olfactory bulb. We describe herein that adult mice mutated in the cell cycle regulatory gene Ccnd2, encoding cyclin D2, lack newly born neurons in both of these brain structures. In contrast, genetic ablation of cyclin D1 does not affect adult neurogenesis. Furthermore, we show that cyclin D2 is the only D-type cyclin (out of D1, D2, and D3) expressed in dividing cells derived from neuronal precursors present in the adult hippocampus. In contrast, all three cyclin D mRNAs are present in the cultures derived from 5-day-old hippocampi, when developmental neurogenesis in the dentate gyrus takes place. Thus, our results reveal the existence of molecular mechanisms discriminating adult versus developmental neurogeneses.

On the transition from the meiotic to mitotic cell cycle during early mouse development

Here, we outline the mechanisms involved in the regulation of cell divisions during oocyte maturation and early cleavages of the mouse embryo. Our interest is focused on the regulation of meiotic M-phases and the first embryonic mitoses that are differently tuned and are characterized by specifically modified mechanisms, some of which have been recently identified. The transitions between the M-phases during this period of development, as well as associated changes in their regulation, are of key importance for both the meiotic maturation of oocytes and the further development of the mammalian embryo. The mouse is an excellent model for studies of the cell cycle during oogenesis and early development. Nevertheless, a number of molecular mechanisms described here were discovered or confirmed during the study of other species and apply also to other mammals including humans.

Ras and Myc can drive oncogenic cell proliferation through individual D-cyclins.

D-type cyclins serve as cell cycle recipients of several oncogenic pathways. The specific sequences of the promoters of the cyclin D genes are thought to render particular D-cyclins responsive to specific oncogenic pathways. For instance, the Ras oncogene was postulated to signal through cyclin D1, while Myc can impact the cell cycle machinery by transcriptionally upregulating cyclin D2. In the current study we engineered mouse fibroblasts to express only cyclin D1, only D2, or only D3. These ‘single-cyclin’ cells allowed us to rigorously test the ability of cyclin D1, D2, or D3, when expressed on their own, to serve as recipients of the Ras- and Myc-driven oncogenic pathways. We found that each of the D-cyclins was sufficient to drive oncogenic proliferation of mouse fibroblasts. This, together with our recent observations that cells lacking all three D-cyclins show greatly reduced susceptibility to the oncogenic action of Ras and Myc, reveals that the Ras and Myc oncogenes can impact the core cell cycle machinery through all three D-cyclins.

Sdf-1 (CXCL12) improves skeletal muscle regeneration via the mobilisation of Cxcr4 and CD34 expressing cells

The regeneration of skeletal muscles involves satellite cells, which are muscle‐specific precursor cells. In muscles, injured either mechanically or as a consequence of a disease, such as muscular dystrophy, local release of the growth factors and cytokines leads to satellite cells activation, proliferation and differentiation of the resulting myoblasts, followed by the formation of new myofibres. Various cell types, such as stem and progenitor cells, originating from other tissues different than the muscle, are also able to follow a myogenic program. Participation of these cells in the repair process depends on their precise mobilisation to the site of the injury.

The First Mitosis of the Mouse Embryo Is Prolonged by Transitional Metaphase Arrest

Abstract The first mitosis of the mouse embryo is almost twice as long as the second. The mechanism of the prolongation of the first mitosis remains unknown, and it is not clear whether prometaphase or metaphase or both are prolonged. Prometaphase is characterized by dynamic chromosome movements and spindle assembly checkpoint activity, which prevents anaphase until establishment of stable kinetochore-microtubule connections. The end of prometaphase is correlated with checkpoint inactivation and disappearance of MAD2L1 (MAD2) and RSN (CLIP-170) proteins from kinetochores. Spindle assembly checkpoint operates during the early mouse mitoses, but it is not clear whether it influences their duration. Here, we determine the length of prometaphases and metaphases during the first two embryonic mitoses by time-lapse video recording of chromosomes and by immunolocalization of MAD2L1 and RSN proteins. We show that the duration of the two prometaphases does not differ and that MAD2L1 and RSN disappear from kinetochores very early during each mitosis. The first metaphase is significantly longer than the second one. Therefore, the prolongation of the first embryonic mitosis is due to a prolonged metaphase, and the spindle assembly checkpoint cannot be involved in this process. We show also that MAD2L1 staining disappears gradually from kinetochores of oocytes arrested at metaphase of the second meiotic division. This shows a striking similarity between the first embryonic mitosis and metaphase arrest in oocytes. We postulate that the first embryonic mitosis is prolonged by a transient metaphase arrest that is independent of the spindle assembly checkpoint and is similar to metaphase II arrest. The molecular mechanism of this transient arrest remains to be elucidated.

Control of duration of the first two mitoses in a mouse embryo.

The duration of M-phase is largely determined by the time necessary for the formation of a functional metaphase spindle and the correct alignment of all chromosomes on the metaphase plate. The spindle assembly checkpoint prevents the exit from M-phase before the proper alignment of all chromosomes on a metaphase plate in many cell types. In the present paper we show that the first mitotic M-phase of the mouse embryo lasts about 119 min, while the second embryonic M-phase lasts only about 70 min. Histone H1 kinase is activated rapidly during nuclear envelope breakdown in both mitoses. Its maximum, however, is followed by a plateau only during the first mitosis. In the second mitosis, the inactivation of histone H1 kinase activity follows its maximum directly. Histone H1 kinase is more stable in the cytoplasts obtained from mouse embryos during the first embryonic M-phase than during the second one. The stability of histone H1 kinase is greatly increased by the presence of the mitotic apparatus in both M-phases. The mitotic spindle assembly during the first and the second mitoses differs and the first metaphase spindle is stabilised during the period of maximum histone H1 kinase activity. These data show that an unknown developmentally regulated mechanism controls the duration of the two first mitoses in the mouse embryo.

Cell cycle regulation during proliferation and differentiation of mammalian muscle precursor cells.

Proliferation and differentiation of muscle precursor cells are intensively studied not only in the developing mouse embryo but also using models of skeletal muscle regeneration or analyzing in vitro cultured cells. These analyses allowed to show the universality of the cell cycle regulation and also uncovered tissue-specific interplay between major cell cycle regulators and factors crucial for the myogenic differentiation. Examination of the events accompanying proliferation and differentiation leading to the formation of functional skeletal muscle fibers allows understanding the molecular basis not only of myogenesis but also of skeletal muscle regeneration. This chapter presents the basis of the cell cycle regulation in proliferating and differentiating muscle precursor cells during development and after muscle injury. It focuses at major cell cycle regulators, myogenic factors, and extracellular environment impacting on the skeletal muscle.

Metaphase I arrest in LT/Sv mouse oocytes involves the spindle assembly checkpoint.

Abstract During meiotic maturation, the majority of oocytes from LT/Sv mice arrest at metaphase I. However, anaphase may be induced through parthenogenetic activation. If this happens within the ovary, it often results in the development of ovarian teratomas. Here, we show that the induction of first meiotic anaphase in LT/Sv oocytes results in incorrect chromosome segregation. In search of the molecular basis of this complex phenotype, we analyzed the localization/destruction of cohesins, as well as the function of the components of the spindle assembly checkpoint (SAC). Both localization and removal of meiotic cohesin REC8 from chromosomes are unperturbed. In contrast, there is prolonged localization of SAC proteins BUB1 and MAD2L1 (MAD2) at the metaphase I kinetochores in mutant oocytes compared with the wild-type. Interfering with BUB1 function through expression of a dominant-negative mutant protein resulted in the increase of the number of LT/Sv oocytes completing the first meiosis, which indicates SAC involvement in metaphase I arrest. These data show for the first time that there is a direct link between the SAC function and the heritable meiotic incompetence of a mammalian oocyte.

Regulation of muscle stem cells activation: the role of growth factors and extracellular matrix.

Vertebrate skeletal muscle is composed of organized multinucleate muscle fibers and also various subpopulations of cells localized in between. Some of them can be considered as the stem cells, however, few of them are able to follow myogenic program. First and most extensively studied so far, are the satellite cells that serve as tissue-specific precursors for muscle growth and repair. They are located between the basal membrane and the sarcolemma of adult muscle myofibers. They remain quiescent but can be activated in response to muscle damage resulted from mechanical injury, stretching, exercise, denervation, or progressing muscle dystrophy. Except the satellite cells also other stem cells could participate in muscle fibers reconstruction. Such cells as pericytes and mesangioblasts, muscle-derived stem cells, including so-called muscle side population, or CD133 expressing cells, were proved to be able to undergo myogenic differentiation in experiments involving their in vitro coculture with myoblasts or transplantation to injured skeletal muscle. In the current review, we will summarize stimuli influencing skeletal muscle stem cells activation, that is, growth factors which are secreted by muscle fibers, satellite cells, inflammatory cells, or released from basal lamina. We will also describe factors present within the skeletal muscle niche which interactions with stem cells lead to their activation, proliferation, asymmetric divisions, migration, and finally differentiation into myotubes, and then terminally differentiated myofibers.