Interplay between lysine methylation and Cdk phosphorylation in growth control by the retinoblastoma protein

As a critical target for cyclin-dependent kinases (Cdks), the retinoblastoma tumour suppressor protein (pRb) controls early cell cycle progression. We report here a new type of regulation that influences Cdk recognition and phosphorylation of substrate proteins, mediated through the targeted methylation of a critical lysine residue in the Cdk substrate recognition site. In pRb, lysine (K) 810 represents the essential and conserved basic residue (SPXK) required for cyclin/Cdk recognition and phosphorylation. Methylation of K810 by the methyltransferase Set7/9 impedes binding of Cdk and thereby prevents subsequent phosphorylation of the associated serine (S) residue, retaining pRb in the hypophosphorylated growth-suppressing state. Methylation of K810 is under DNA damage control, and methylated K810 impacts on phosphorylation at sites throughout the pRb protein. Set7/9 is required for efficient cell cycle arrest, and significantly, a mutant derivative of pRb that cannot be methylated at K810 exhibits compromised cell cycle arrest. Thus, the regulation of phosphorylation by Cdks reflects the combined interplay with methylation events, and more generally the targeted methylation of a lysine residue within a Cdk-consensus site in pRb represents an important point of control in cell cycle progression.     

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.     

Interplay between autophagy and programmed cell death in mammalian neural stem cells

Mammalian neural stem cells (NSCs) are of particular interest because of their role in brain development and function. Recent findings suggest the intimate involvement of programmed cell death (PCD) in the turnover of NSCs. However, the underlying mechanisms of PCD are largely unknown. Although apoptosis is the best-defined form of PCD, accumulating evidence has revealed a wide spectrum of PCD encompassing apoptosis, autophagic cell death (ACD) and necrosis. This mini-review aims to illustrate a unique regulation of PCD in NSCs. The results of our recent studies on autophagic death of adult hippocampal neural stem (HCN) cells are also discussed. HCN cell death following insulin withdrawal clearly provides a reliable model that can be used to analyze the molecular mechanisms of ACD in the larger context of PCD. More research efforts are needed to increase our understanding of the molecular basis of NSC turnover under degenerating conditions, such as aging, stress and neurological diseases. Efforts aimed at protecting and harnessing endogenous NSCs will offer novel opportunities for the development of new therapeutic strategies for neuropathologies. [BMB Reports 2013; 46(8): 383-390]     

The subpopulation of mesenchymal stem cells that differentiate toward cardiomyocytes is cardiac progenitor cells

Mesenchymal stem cells (MSCs) are regarded as a promising source of cell-based therapy for heart injury. In fact, less than 30% of MSCs contribute to cardiomyocytes differentiation, and the isolation procedure and biological characteristics of this population of cells remain unknown. Here we isolate and investigate the biological characteristics of this subpopulation of MSCs. Twenty four MSC clones were randomly selected using single-cell monoclonal technology. After induced with 5-azacytidine, eight clones displayed cardiomyocyte-like morphologies, and highly (over 90%) expressed cardiac-specific markers cTnT and α-actin, and displayed transient outward K⁺ current (I_to), inwardly rectifying K⁺ current (I_K1) and delayed rectifier K⁺ current (I_KDR), which were typical of cardiomocytes. Other clones merely showed I_to current, and the current densities were different from those of cardiomyocytes. In contrast to the other clones, before induced with 5-azacytidine, the eight clones expressed early cardiac markers GATA4 and NKX2.5, but not cTnT, α-actin, CD44 and CD90, and had no potentials for adiopogenesis, osteogenesis or chondrogenesis after induction. Our data suggest that the subgroup of MSCs that contributes to cardiomyocytes differentiation is cardiac progenitor cells. Moreover, we show the preliminary purification of this population of cells with a high potential for cardiomyocytes differentiation using single-cell monoclonal technology.     

Protein tyrosine phosphatase 1B (PTP1B) is required for cardiac lineage differentiation of mouse embryonic stem cells

Protein tyrosine phosphatase 1B (PTP1B) has been shown to regulate multiple cellular events such as differentiation, cell growth, and proliferation; however, the role of PTP1B in differentiation of embryonic stem (ES) cells into cardiomyocytes remains unexplored. In the present study, we investigated the effects of PTP1B inhibition on differentiation of ES cells into cardiomyocytes. PTP1B mRNA and protein levels were increased during the differentiation of ES cells into cardiomyocytes. Accordingly, a stable ES cell line expressing PTP1B shRNA was established. In vitro, the number and size of spontaneously beating embryoid bodies were significantly decreased in PTP1B-knockdown cells, compared with the control cells. Decreased expression of cardiac-specific markers Nkx2-5, MHC-α, cTnT, and CX43, as assessed by real-time PCR analysis, was further confirmed by immunocytochemistry of the markers. The results also showed that PTP1B inhibition induced apoptosis in both differentiated and undifferentiated ES cells, as presented by increasing the level of cleaved caspase-3, cytochrome C, and cleaved PARP. Further analyses revealed that PTP1B inhibition did not change proliferation and pluripotency of undifferentiated ES cells. Taken together, the data presented here suggest that PTP1B is essential for proper differentiation of ES cells into cardiomyocytes.     

Interplay between in vitro acetylation and phosphorylation of tailless HMGB1 protein

The postsynthetic acetylation of HMGB1 protein and its truncated form affects significantly its properties as “architectural” factor - recognition of bent DNA and bending of short DNA fragments. We created mutants at the target sites (lysines 2 and 81) in the tailless HMGB1 modified by the histone acetyltransferase CBP. The results show that there is no preferential site for the enzymatic activity of CBP and both lysine moieties are modified independently. Our findings for the first time demonstrate the link between the acetylation and phosphorylation of HMGB1ΔC in vitro. The PKC phosphorylation prior to acetylation inhibits the CBP activity 40-60% for the truncated form and its mutants. The effect of the CBP acetylation on the phosphorylation level turns out to be much more prominent. In the case of HMGB1ΔC modified at Lys 2 and Lys 81 prior to PKC treatment background phosphorylation is detected. If only one of the lysines is modified the inhibitory effect decreases.     

Steering signal transduction pathway towards cardiac lineage from human pluripotent stem cells: A review

In humans injured myocardium cannot avert the onset and progression of ventricular dysfunction because of limited regenerative ability of myocytes. Although limited renaissance of cardiomyocytes has been reported in human infarcted hearts, it is generally accredited that non-functional fibrous tissue replaces the dead myocardium. High cardiovascular morbidity and dearth of donor hearts warrant a constant hunt for radically different approach to treat heart failure. Pluripotent stem (PS) cells possess the ability to produce functional cardiomyocytes for clinical applications and drug development, which may provide the answer to this problem. Although progress has been made in differentiating human PS cells into cardiomyocytes, however, the in vitro differentiation of pluripotent cells into cardiomyocytes involves a poorly defined, inefficient and relatively non-selective process. A thorough understanding of signaling pathways would tender a roadmap for the streamlined development of in vitro cardiac differentiation strategies. The ability to obtain unlimited numbers of human cardiomyocytes would improve development of cell-based therapies for cardiovascular diseases, facilitate the study of cardiovascular biology and improve the early stages of drug discovery. Here in this review, we highlight the interacting endogenous cellular signals and their modulators involved in directing the human PSCs towards cardiac differentiation.     

Interplay between human high mobility group protein 1 and replication protein A on psoralen-cross-linked DNA

Human high mobility group box (HMGB) 1 and -2 proteins are highly conserved and abundant chromosomal proteins that regulate chromatin structure and DNA metabolism. HMGB proteins bind preferentially to DNA that is bent or underwound and to DNA damaged by agents such as cisplatin, UVC radiation, and benzo[a]pyrenediol epoxide (BPDE). Binding of HMGB1 to DNA adducts is thought to inhibit nucleotide excision repair (NER), leading to cell death, but the biological roles of these proteins remain obscure. We have used psoralen-modified triplex-forming oligonucleotides (TFOs) to direct a psoralen-DNA interstrand cross-link (ICL) to a specific site to determine the effect of HMGB proteins on recognition of these lesions. Our results reveal that human HMGB1 (but not HMGB2) binds with high affinity and specificity to psoralen ICLs, and interacts with the essential NER protein, replication protein A (RPA), at these lesions. RPA, shown previously to bind tightly to these lesions, also binds in the presence of HMGB1, without displacing HMGB1. A discrete ternary complex is formed, containing HMGB1, RPA, and psoralen-damaged DNA. Thus, HMGB1 has the ability to recognize ICLs, can cooperate with RPA in doing so, and likely modulates their repair by the NER machinery. The abundance of HMGB1 suggests that it may play an important role in determining the sensitivity of cells to DNA damage under physiological, experimental, and therapeutic conditions.     

Functional interactions between the estrogen receptor coactivator PELP1/MNAR and retinoblastoma protein

PELP1 (proline-, glutamic acid-, and leucine-rich protein-1 (also referred to as MNAR, or modulator of nongenomic activity of estrogen receptor)), a recently identified novel coactivator of estrogen receptors, is widely expressed in a variety of 17 beta-estradiol (E2)-responsive reproductive tissues and is developmentally regulated in mammary glands. pRb (retinoblastoma protein), a cell cycle switch protein, plays a fundamental role in the proliferation, development, and differentiation of eukaryotic cells. To study the putative function of PELP1, we established stable MCF-7 breast cancer cell lines overexpressing PELP1. PELP1 overexpression hypersensitized breast cancer cells to E2 signaling, enhanced progression of breast cancer cells to S phase, and led to persistent hyperphosphorylation of pRb in an E2-dependent manner. Using phosphorylation site-specific pRb antibodies, we identified Ser-807/Ser-811 of pRb as a potential target site of PELP1. Interestingly, PELP1 was discovered to be physiologically associated with pRb and interacted via its C-terminal pocket domain, and PELP1/pRb interaction could be modulated by antiestrogen agents. Using mutant pRb cells, we demonstrated an essential role for PELP1/pRb interactions in the maximal coactivation functions of PELP1 using cyclin D1 as one of the targets. Taken together, these findings suggest that PELP1, a steroid coactivator, plays a permissive role in E2-mediated cell cycle progression, presumably via its regulatory interaction with the pRb pathway.     

Troika of the mouse blastocyst: lineage segregation and stem cells

The initial period of mammalian embryonic development is primarily devoted to cell commitment to the pluripotent lineage, as well as to the formation of extraembryonic tissues essential for embryo survival in utero. This phase of development is also characterized by extensive morphological transitions. Cells within the preimplantation embryo exhibit extraordinary cell plasticity and adaptation in response to experimental manipulation, highlighting the use of a regulative developmental strategy rather than a predetermined one resulting from the non-uniform distribution of maternal information in the cytoplasm. Consequently, early mammalian development represents a useful model to study how the three primary cell lineages; the epiblast, primitive endoderm (also referred to as the hypoblast) and trophoblast, emerge from a totipotent single cell, the zygote. In this review, we will discuss how the isolation and genetic manipulation of murine stem cells representing each of these three lineages has contributed to our understanding of the molecular basis of early developmental events.