Antitumor protein (AP) from a mushroom induced apoptosis to transformed human keratinocyte by controlling the status of prb, c-MYC, cyclin E-cdk2, and p21WAF1 in the G1/S transition

Antitumor protein (AP) from a mushroom, induced the morphological changes typical to apoptosis such as nuclear condensation, aneuploidity, and DNA fragmentation at concentrations as low as 5-20 ng/ml to cancer cells. Molecular alterations related to cell cycle. Molecular alterations related to cell cycle, especially G1/S transition were investigated with a human keratinocyte transformed with oncoproteins, E6 and E7 of human pappiloma virus(HPV)-16. AP didn't alter significantly and oncosuppressor p53 level, but induced hyperphosphorylation of pRb. Time-dependent change of G1 cyclins, cdk2 and cdk4 after addition of AP showed that expression level of cdk inhibitors, INK4 family, and p27KIP1 did not altered, while that of p21WAF1 was downregulated.     

Beyond the cell cycle: a new role for Cdk6 in differentiation

Over 10 years ago, cdk6 was identified as a new member in a family of vertebrate cdc-2 related kinases. This novel kinase was found to partner with the D-type cyclins and to possess pRb kinase activity in vitro and has since been understood to function solely as a pRb kinase in the regulation of the G(1) phase of the cell cycle. In the past 2 years, several independent studies in multiple cell types have indicated a novel role for cdk6 in differentiation. For example, cdk6 expression must be reduced to allow proper osteoblast and osteoclast differentiation, forced cdk6 expression blocked differentiation of mouse erythroid leukemia cells and cdk6 expression in primary astrocytes favors the expression of progenitor cell markers. Since exit from the cell cycle is a necessary step in terminal differentiation, down-regulation of a mitogenic factor may be expected in this process, however it is surprising that this association has not been previously uncovered and that it is apparently not shared with cdk4, long understood to be a functional homolog of cdk6. The mechanism of cdk6 function in differentiation is not understood, but it may extend beyond the established role of cdk6 as a pRb kinase. As this story unfolds it will be important to discover if the function of cdk6 in differentiation is pRb-dependent or pRb-independent, since pRb has long been established as a key factor in initiating and maintaining cell cycle exit during differentiation.     

Multiple Functions of D-Type Cyclins Can Antagonize pRb-Mediated Suppression of Proliferation

The most well understood function of the D-type cyclins is to activate the G1kinases, cdk4 and cdk6, and target the retinoblastoma gene product (pRb) forphosphorylation and inactivation. pRb can suppress S phase entry, cause a transientG1 arrest following DNA damage, and is critical in establishing terminal cell cyclewithdrawal in cells exposed to differentiation or senescence-inducing signals. Each ofthese functions of pRb can be demonstrated in cultured cells derived from humantumors that have suffered RB1 gene inactivation. In such in vitro assays, coexpressionof D type cyclins has been shown to inhibit the function of pRb, likelyreflecting an oncogenic role of cyclin D1 in vivo. Two regions of cyclin D, the LxCxEpRb-binding motif, and the cyclin box, are thought to be critical for the proper functionof cyclin D. Here we show that the LxCxE motif is dispensable in cyclin D1 for allfunctions tested, but is required by cyclin D2. This observation suggests that there isa functional difference between cyclins D1 and D2 in pRb regulation, and arguesagainst complete functional redundancy of these D cyclins. In addition, the ability ofcyclins D1 and D2 to activate cdk partners is required for induction of pRbphosphorylation and S phase entry. However, mutant forms of cyclins D1 and D2that are incapable of activating kinase partners were still able to prevent pRb-inducedsenescence. Thus, D cyclins have both kinase-dependent and kinase-independentmechanisms of interfering with proliferation arrest and senescence.     

CDC2-related kinase PITALRE phosphorylates pRb exclusively on serine and is widely expressed in human tissues

Mammalian cell cycle progression is regulated by sequential activation and inactivation of cyclin-dependent kinases (cdks). Recently, several new members of the cdk family were cloned, and some of these were shown to complex with different cyclins and to be active at discrete stages of the cell cycle. PITALRE, a new member of this family, was cloned by our laboratory and was shown to be able to phosphorylate pRb protein in vitro. In the current work, we found that PITALRE kinase activity phosphorylated pRb at sites similar to those phosphorylated by the CDC2 kinase, which itself is known to mimic, in vitro, the in vivo phosphorylation of pRb. Phosphorylation of pRb by the PITALRE-associated kinase activity was on Ser residues exclusively. Moreover, we investigated the expression pattern of PITALRE in normal human tissues, using immunohistochemical techniques so as to gain additional data on the characteristics of this new cdk family member. The protein was widely expressed, although a different tissue distribution and/or level of expression was found in various organs. Some specialized tissues such as blood, lymphoid tissue, ovarian cells, and the endocrine portion of the pancreas showed a high expression level of PITALRE. The specific expression pattern found suggests that PITALRE may be involved in specialized functions in certain cell types. J. Cell. Physiol. 172:265–273, 1997. © 1997 Wiley-Liss, Inc.     

From Cell Cycle to Differentiation: An Expanding Role for Cdk6

Over ten years ago, cdk6 was identified as a new member in a family of vertebrate cdc-2 related kinases. This novel kinase was found to partner with the D-type cyclins and to possess pRb kinase activity in vitro. 1 Recently, several independent studies in multiple cell types have indicated a novel role for cdk6 in differentiation. Since exit from the cell cycle is a necessary step in the process of differentiation, it may not seem surprising that down-regulation of a mitogenic factor may be required for this process. It is, however, surprising that this association has not been previously uncovered and that it is apparently not a shared with cdk4, long understood to be a functional homolog of cdk6. As this story unfolds it will be important to discover if the role of cdk6 in differentiation is pRb-dependent or pRb-independent, since pRb has long been established as a key factor in initiating and maintaining cell cycle exit during differentiation.     

Inhibition of cyclin-dependent kinase activity triggers neuronal differentiation of mouse neuroblastoma cells

Studies on the molecular mechanisms underlying neuronal differentiation are frequently performed using cell lines established from neuroblastomas. In this study we have used mouse N1E-115 neuroblastoma cells that undergo neuronal differentiation in response to DMSO. During differentiation, cyclin-dependent kinase (cdk) activities decline and phosphorylation of the retinoblastoma gene product (pRb) is lost, leading to the appearance of a pRb-containing E2F DNA-binding complex. The loss of cdk2 activity is due to a decrease in cdk2 abundance whereas loss of cdk4 activity is caused by strong association with the cdk inhibitor (CKI) p27KIP1 and concurrent loss of cdk4 phosphorylation. Moreover, neuronal differentiation can be induced by overexpression of p27KIP1 or pRb, suggesting that inhibition of cdk activity leading to loss of pRb phosphorylation, is the major determinant for neuronal differentiation.     

Cyclin D3 is dispensable for human diffuse large B-cell lymphoma survival and growth: evidence for redundancy with cyclin E

Genomic changes disrupting the expression of cyclin D3 are associated with aberrant growth of several human B-lymphoid malignancies. We demonstrate that the human diffuse large B-cell lymphoma (DLBCL), OCI-LY18 (LY18) expresses cyclin D3 but not cyclins D1 and D2. RNA interference was used to deplete cyclin D3 from LY18 cells. Surprisingly, knockdown of cyclin D3 did not inhibit pRb phosphorylation on cdk4/6- and cdk2-specific residues or measurably affect viability and proliferation. These results suggest that cyclin D3 is dispensable in LY18 cell proliferation and survival. Similar results were obtained following depletion of cyclin E. By contrast, combined knockdown of cyclins D3 and E had substantial consequences leading to G1-phase arrest and inhibition of proliferation. Whereas cell cycle distribution was not affected following individual depletion of cdk4, cdk6, or cdk2, the combined knockdown of cdk4 and cdk6 led to accumulation of LY18 cells in G1-phase of the cell cycle and inhibition of proliferation. Likewise treatment of LY18 cells with 2-Bromo-12,13-dihydro-5H-indolo[2,3-a]pyrrolo[3,4-c]carbazole-5,7(6H)-dione, a selective inhibitor of cdk4/6, led to inhibition of proliferation. Taken together, these results uncover a built-in redundancy with cyclins D3 and E for G1-S progression. Moreover these findings highlight the rationale for simultaneous disruption of cdk4/6 as a potential therapeutic cancer strategy.     

Desmoglein 1–dependent suppression of EGFR signaling promotes epidermal differentiation and morphogenesis

Dsg1 (desmoglein 1) is a member of the cadherin family of Ca²⁺-dependent cell adhesion molecules that is first expressed in the epidermis as keratinocytes transit out of the basal layer and becomes concentrated in the uppermost cell layers of this stratified epithelium. In this study, we show that Dsg1 is not only required for maintaining epidermal tissue integrity in the superficial layers but also supports keratinocyte differentiation and suprabasal morphogenesis. Dsg1 lacking N-terminal ectodomain residues required for adhesion remained capable of promoting keratinocyte differentiation. Moreover, this capability did not depend on cytodomain interactions with the armadillo protein plakoglobin or coexpression of its companion suprabasal cadherin, Dsc1 (desmocollin 1). Instead, Dsg1 was required for suppression of epidermal growth factor receptor–Erk1/2 (extracellular signal-regulated kinase 1/2) signaling, thereby facilitating keratinocyte progression through a terminal differentiation program. In addition to serving as a rigid anchor between adjacent cells, this study implicates desmosomal cadherins as key components of a signaling axis governing epithelial morphogenesis.