R. Wayne Albers scite author profile

Because the asthmatic bronchial epithelium is characterized by widespread damage, we postulated that this is associated with expression of cell cycle inhibitors that control proliferation. Using bronchial biopsies, the epithelium was the major site of expression of the cyclin-dependent kinase inhibitor, p21(waf). Immunostaining usually occurred in the cytoplasm of columnar cells; however, in severe asthma, nuclear staining was also evident in the proliferative, basal cell compartment. p21(waf) expression was significantly higher in asthmatic versus nonasthmatic epithelium and was unaffected by corticosteroid treatment; proliferating cell nuclear antigen was not significantly different in any group. p21(waf), but not p27(kip1), mRNA and protein were induced by treatment of bronchial epithelial cells in vitro with transforming growth factor (TGF)-beta or H2O2, but not by dexamethasone, which induced p57(kip2). TGF-beta and dexamethasone inhibited epidermal growth factor (EGF)-induced DNA synthesis, whereas low concentrations of H2O2 synergized with EGF; at higher doses, growth inhibition and induction of apoptosis occurred. TGF-beta caused p21(waf) to become nuclear, suggesting interaction with the replicative machinery; however, in oxidant-stressed cells, p21(waf) was predominantly cytoplasmic, where it has been linked to cell survival. We conclude that p21(waf) overexpression in asthma influences cell proliferation and survival. This may cause abnormal repair responses that contribute to airway inflammation and remodeling.

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Regulation of cyclin-dependent kinase 5 catalytic activity by phosphorylation

Sharma

Amin

et al. 1999

Proc. Natl. Acad. Sci. U.S.A.

103

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Cyclin-dependent kinase 5 (cdk5) is found in an active form only in neuronal cells. Activation by virtue of association with the cyclin-like neuronal proteins p35 (or its truncated form p25) and p39 is the only mechanism currently shown to regulate cdk5 catalytic activity. In addition to cyclin binding, other members of the cdk family require for maximal activation phosphorylation of a Ser͞Thr residue (Thr 160 in the case of cdk-2) that is conserved in all cdks except cdk8. This site is phosphorylated by cdk-activating kinases, which, however, do not phosphorylate cdk5. To examine the possible existence of a phosphorylation-dependent regulatory mechanism in the case of cdk5, we have metabolically labeled PC12 cells with 32 P i and shown that the endogenous cdk5 is phosphorylated. Bacterially expressed cdk5 also can be phosphorylated by PC12 cell lysates. Phosphorylation of cdk5 by a PC12 cell lysate results in a significant increase in cdk5͞p25 catalytic activity. Ser 159 in cdk5 is homologous to the regulatory Thr 160 in cdk2. A Ser 159 -to-Ala (S159A) cdk5 mutant did not show similar activation, which suggests that cdk5 is also regulated by phosphorylation at this site. Like other members of the cdk family, cdk5 catalytic activity is inf luenced by both p25 binding and phosphorylation. We show that the cdk5-activating kinase (cdk5AK) is distinct from the cdk-activating kinase (cyclin H͞cdk7) that was reported previously to neither phosphorylate cdk5 nor affect its activity. We also show that casein kinase I, but not casein kinase II, can phosphorylate and activate cdk5 in vitro.Cyclin-dependent kinase 5 (cdk5) is a serine͞threonine kinase present at relatively high levels in neurons (1, 2). On the basis of sequence similarity, it is a member of the cyclin-dependent kinase (cdk) family. Full activation of cyclin-dependent kinases characteristically requires combination with one of the cyclins and also phosphorylation of a threonine or serine residue located on the cdk T loop by a cdk-activating kinase. These two events are considered to act cooperatively to open the catalytic site and relieve its obstruction by the T loop (3-6). However, cdk5 is not activated by cyclins, and activation by phosphorylation of its T loop serine has not been demonstrated previously (3). Activation of cdk5 results instead from combination with cdk5-specific activators that include p35 or its truncated form, p25 (7,8), and p39 (9). Although cdk5 is expressed in many mammalian tissues, the cdk5 activators are largely restricted to neurons. The mechanism of cdk5 interaction with its activators is thought to be analogous to that of cyclindependent kinases and forms highly stable and active complexes after prolonged incubation (7-10). Substrates of cdk5 include the neuronal cytoskeletal proteins neurofilament-H (1, 11), tau (12), and MAP (13). However, the embryonic lethality of cdk-5 ''knockout'' mice suggests additional important functions for this enzyme (14).Because cdk-activating kinase (cyclin H͞cdk7) has been found not to ...

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Intermolecular Conformational Coupling and Free Energy Exchange Enhance the Catalytic Efficiency of Cardiac Muscle SERCA2a following the Relief of Phospholamban Inhibition

et al. 2005

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Activation of cardiac muscle sarcoplasmic reticulum Ca2+-ATPase (SERCA2a) by beta1-agonists involves cAMP- and PKA-dependent phosphorylation of phospholamban (PLB), which relieves the inhibitory effects of PLB on SERCA2a. To investigate the mechanism of SERCA2a activation, we compared the kinetic properties of SERCA2a expressed with (+) and without (-) PLB in High Five insect cell microsomes to those of SERCA1 and SERCA2a in native skeletal and cardiac muscle SR. Both native SERCA1 and expressed SERCA2a without PLB exhibited high-affinity (10-50 microM) activation of pre-steady-state catalytic site dephosphorylation by ATP, steady-state accumulation of the ADP-sensitive phosphoenzyme (E1P), and a rapid phase of EGTA-induced phosphoenzyme (E2P) hydrolysis. In contrast, SERCA2a in native cardiac SR vesicles and expressed SERCA2a with PLB lacked the high-affinity activation by ATP and the rapid phase of E2P hydrolysis, and exhibited low steady-state levels of E1P. The results indicate that the kinetic differences in Ca2+ transport between skeletal and cardiac SR are due to the presence of phospholamban in cardiac SR, and not due to isoform-dependent differences between SERCA1 and SERCA2a. Therefore, the results are discussed in terms of a model in which PLB interferes with SERCA2a oligomeric interactions, which are important for the mechanism of Ca2+ transport in skeletal muscle SERCA1 [Mahaney, J. E., Thomas, D. D., and Froehlich, J. P. (2004) Biochemistry 43, 4400-4416]. We propose that intermolecular coupling of SERCA2a molecules during catalytic cycling is obligatory for the changes in Ca2+ transport activity that accompany the relief of PLB inhibition of the cardiac SR Ca2+-ATPase.

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R. Wayne Albers

Biochemical Aspects of Active Transport

Increased Expression of p21^waf Cyclin-Dependent Kinase Inhibitor in Asthmatic Bronchial Epithelium

Regulation of cyclin-dependent kinase 5 catalytic activity by phosphorylation

Intermolecular Conformational Coupling and Free Energy Exchange Enhance the Catalytic Efficiency of Cardiac Muscle SERCA2a following the Relief of Phospholamban Inhibition

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About

R. Wayne Albers

Biochemical Aspects of Active Transport

Increased Expression of p21waf Cyclin-Dependent Kinase Inhibitor in Asthmatic Bronchial Epithelium

Regulation of cyclin-dependent kinase 5 catalytic activity by phosphorylation

Intermolecular Conformational Coupling and Free Energy Exchange Enhance the Catalytic Efficiency of Cardiac Muscle SERCA2a following the Relief of Phospholamban Inhibition

Contact Info

Product

Resources

About

Increased Expression of p21^waf Cyclin-Dependent Kinase Inhibitor in Asthmatic Bronchial Epithelium