The K+ battery-regulating Arabidopsis K+ channel AKT2 is under the control of multiple post-translational steps

Potassium (K⁺) is an important nutrient for plants. It serves as a cofactor of various enzymes and as the major inorganic solute maintaining plant cell turgor. In a recent study, an as yet unknown role of K⁺ in plant homeostasis was shown. It was demonstrated that K⁺ gradients in vascular tissues can serve as an energy source for phloem (re)loading processes and that the voltage-gated K⁺ channels of the AKT2-type play a unique role in this process. The AKT2 channel can be converted by phosphorylation of specific serine residues (S210 and S329) into a non-rectifying channel that allows a rapid efflux of K⁺ from the sieve element/companion cells (SE/CC) complex. The energy of this flux is used by other transporters for phloem (re)loading processes. Nonetheless, the results do indicate that post-translational modifications at S210 and S329 alone cannot explain AKT2 regulation. Here, we discuss the existence of multiple post-translational modification steps that work in concert to convert AKT2 from an inward-rectifying into a non-rectifying K⁺ channel.Key words: potassium, channel, potassium channel, AKT2, phloem (re)loading, post-translational modifications, potassium batteryPotassium (K⁺) is the most abundant mineral element in plants, and together with nitrogen and phosphorous, is limiting for plant production in many natural and agricultural habitats. Voltage-gated K⁺ channels are key players in the acquisition of K⁺ ions from the soil and in its redistribution within the plant.¹ Structurally, these channels result from the assembly of four so-called α-subunits. The subunits are encoded by nine genes in Arabidopsis and both homo- and hetero-tetramers are expressed.^2,3 The K⁺ channel α-subunits can be categorized into four different subfamilies, based on the voltage-gating characteristics of the exogenous K⁺ conductance when expressed in an appropriate heterologous expression system. K_in α-subunits form hyperpolarization-activated channels that mediate K⁺ uptake.^4–7 K_out α-subunits form depolarization-activated channels that mediate K⁺ release from cells.^8–10 K_silent subunits appear unable to yield functional homomeric channels, but can combine with K_in subunits and fine-tune the K⁺-uptake properties of the resulting heteromeric channels.^11–14 Finally, K_weak α-subunits form channels with complex voltage-gating; they allow both K⁺ uptake and release.^15–19 In Arabidopsis, a single member is found in this subfamily, AKT2, and this channel can assemble in heteromeric channels with the K_in subunit KAT2.²⁰To date, only scarce and speculative information has been obtained for the function of K_weak channels. When expressed in heterologous expression systems, two different subpopulations of AKT2 channels differing in their sensitivity to voltage were found.²¹ Channels of the first type showed gating properties and currents analogous to that of K_in channels, while the other sort enabled a non-rectified (leak-like) current; they were open over the entire physiological voltage range.A given channel can be converted from one type to the other by post-translational modifications.²¹ A voltage-dependent phosphorylation was found to be an essential step for this switch,^22,23 although the kinase responsible for this conversion still needs to be uncovered.²⁴ In biophysical studies, mutant versions of the Arabidopsis K_weak channel subunit AKT2 have been created that showed impaired gating mode settings.^22,23 Recently, Gajdanowicz et al. generated transgenic Arabidopsis thaliana plants that express these mutant AKT2 channels in the background of the akt2-1 null-allele plant.²⁵ The major conclusion from analyses of these mutants is that the status switching of AKT2 from an inward-rectifying to a non-rectifying channel is crucial for plants to overcome energy-limiting conditions. This function of AKT2 could be correlated to its expression in phloem tissues. Selective expression of AKT2 under the control of the phloem companion cell-specific AtSUC2 promoter rescued the akt2-1 line, but conversely, selective expression of AKT2 under the control of the guard cell-specific GC1 promoter,²⁶ resulted in further impairment of plant growth (Fig. 1). By combining diverse experimental approaches with mathematical simulation methods, an existing model for phloem (re)loading^18,27 was fundamentally improved. This allowed the uncovering of a novel and interesting role of K⁺ in phloem physiology: K⁺ gradients present between the sieve element/companion cell (SE/CC) complex and the apoplast can serve as an energy source in phloem (re)loading processes. This “potassium battery” can be tapped by means of AKT2 regulation. This clarifies the observation of Deeken et al.²⁸ that in AKT2 loss-of-function mutant plants, assimilates leaking away from the sieve tube were not efficiently reloaded into the main phloem stream.Open in a separate windowFigure 1AKT2 expressed only in guard cells delays plant development. (A–C) Representative wild-type, akt2-1 and akt2-1+pGC1:AKT2 complementation plants grown for 7 weeks (A), 9 weeks (B) and 12 weeks (C) under 12-h day/12-h night conditions at normal light intensity (150 µmol m⁻² s⁻¹). (D) akt2-1+pGC1:AKT2 developed a similar number of leaves as the akt2-1 knock out plants, but bolting-time was delayed. (B and E) After 9 weeks, wild-type plants were at an advanced bolting stage, akt2-1 plants had started bolting, but only initial signs of bolting were visible in akt2-1+pGC1:AKT2 plants. (C and F) At 12 weeks, akt2-1 plants had caught up with the wild-type and akt2-1+pGC1:AKT2 was just starting to bolt, although rosette-leaves were showing clear signs of senescence. For the generation of akt2-1+pGC1:AKT2, the AKT2 cDNA was fused to the guard cell-specific GC1 promoter²⁶ kindly provided by J.I. Schroeder, San Diego. The pGC1:AKT2 construct was cloned into pGreen0229-35S by replacing the 35S promoter and then transformed into the akt2-1 knockout plant. All seeds were cold-treated for 24 h at 4°C. Plants were grown on artificial substrate (type GS-90, Einheitserde). After 2 weeks, seedlings were transferred to single pots. Plants were grown in 60% relative humidity at 21°C during the day and 18°C at night. Phenotypical analyses were done in the middle of the day. Data are shown as means ± SD of n ≥ 9 plants. Statistical analyses using Student''s t test: (D, WT/akt2-1: p < 2e-08; D, WT/pGC-AKT2: p < 2e-08; D, akt2-1/pGC-AKT2: p < 5e-03; E, WT/akt2-1: p < 4e-06; E, WT/pGC-AKT2: p < 1e-10; E, akt2-1/pGC-AKT2: p < 5e-04; F, WT/akt2-1: p = 0.51; F, WT/pGC-AKT2: p < 1e-10; F, akt2-1/pGC-AKT2: p < 1e-10).AKT2 expression is especially abundant in phloem tissues and the root stele, both of which are characterized by a poor availability of oxygen.^29,30 This local internal hypoxia impairs respiratory activity of the vascular tissue and concomitantly, respiratory ATP production is reduced.³¹ As a consequence, phloem transport is very susceptible to decreasing oxygen supply to the plant.^29,32 It is therefore comprehensible that the above mentioned support by the K⁺ driving force for sucrose retrieval is especially relevant in the phloem. Indeed Gajdanowicz et al.²⁵ showed that transgenic plants lacking the AKT2 K⁺ channel were severely impaired in growth when exposed to mild hypoxia (10% v:v), whereas growth of wild-type plants was unaffected by this treatment. These observations illustrate the importance of biochemical flexibility in plant cells to cope with the energetic consequences of the steep oxygen concentration gradients that generally occur in plant stems and roots.In fact, the role of K⁺ gradients in driving sugar, amino acid and organic acid transport across plant cell membranes was first suggested several decades ago.^33,34 Experimental evidence for this concept was provided by various tests in which pieces of plant tissue were incubated in solutions with different K⁺ concentrations and pH levels.^33,34 Unfortunately, at that time the lack of genetic information to support this hypothesis (e.g., identifying transporter proteins that could provide a molecular mechanism to explain the working mechanism of substrate transport driven by a K⁺-motive force) resulted in this idea falling into oblivion. Indeed, the unequivocal experimental observation of this new role of K⁺ gradients in phloem reloading is extremely challenging. Under normal experimental conditions, K⁺ fluxes and sucrose fluxes are coupled during phloem loading in source tissues and unloading in sink tissues. Nonetheless, computational simulations predict that under certain conditions, a local K⁺/Suc antiport is also thermodynamically possible. In this antiport system, the energy from the K⁺ gradient is used to transport Suc into the phloem. This process is only transient; flooding the apoplast with K⁺ will decrease the K⁺ gradient. However, the gradient can be maintained for longer if surrounding cells take up the apoplastic K⁺ for their own use. A K⁺/Suc antiport will not occur in obvious sink or source tissues since the energy balances in such cells are fundamentally different. Consequently, in these tissues only the coupled symport of K⁺ and Suc can be observed. However, the computational predictions allowed the identification of the experimental conditions under which the effect of the K⁺/Suc antiport system is empirically observable at the whole plant level.An essential role in the regulation of AKT2 is played by (de)phosphorylation events of serine residues at positions S210 and S329. The replacement of both serines by asparagine (AKT2-S210N-S329N) resulted in a K⁺-selective leak that is locked in a continuously open mode when the channels are expressed in Xenopus oocytes. Under certain conditions, plants expressing the AKT2-S210N-S329N mutation showed growth benefits over wild-type plants; akt2-1+AKT2-S210N-S329N plants reach the generative state faster, possess an increased number of leaves and increased fresh weight (Fig. 2). Intuitively, one would expect a continuously open channel to cause severe problems for the plant, not a benefit as was observed here. We therefore have to postulate that phosphorylation at residues AKT2-S210 and AKT2-S329 is insufficient for converting AKT2 from an inward-rectifying into a non-rectifying channel; other, as yet unknown mechanisms, must contribute to the switch in the AKT2 gating mode. Such a concept would correspond to results that would otherwise be hard to explain. For instance, when both serine residues were replaced by glutamate, the mutant AKT2-S210E-S329E still showed wild-type characteristics.²² The S to E substitution is expected to mimic the phosphorylated state better than the S to N replacement. Furthermore, position AKT2-K197 has a fundamental influence on the AKT2 gating mode.²³ AKT2 mutants with that particular lysine substituted with a serine are far less sensitive towards (de)phosphorylation; they display the characteristics of a pure inward-rectifying K⁺ channel,²³ and transgenic Arabidopsis plants expressing AKT2 channels with this substitution showed the characteristics of akt2-1 knock-out plants.²⁵ Initially, it was proposed that the positive charge is important for sensitizing AKT2 to phosphorylation. However, the charge-conserving mutant AKT2-K197R is similar to the charge inverting mutant AKT2-K197D,²³ a purely inward-rectifying channel (Fig. 3). We therefore need to take into account that in plants, K197 may also be a target of post-translational modification.³⁵ At present, we can explain the beneficial effect of the AKT2-S210N-S329N mutant on plant growth only by a multiple step regulation of AKT2 (Fig. 4). The double-N mutation would then bypass the phosphorylation step, but AKT2-S210N-S329N could still be deregulated into an inward-rectifying channel. Thus, AKT2 can be considered as a highly specialized K_in channel that can be converted into a leak-like channel by a cascade of post-translational modification steps.Open in a separate windowFigure 2Plants expressing the AKT2-S210N-S329N mutant reach the generative state faster than wild-type plants. The mutant channel AKT2-S210N-S329N was expressed under the control of the native AKT2 promoter in the akt2-1 knock-out background. (A) Photos of representative Arabidopsis thaliana plants grown 7 weeks under short day conditions (12-h day/12-h night, light intensity = 150 µE m⁻²s⁻¹). Seven weeks after sowing, plants expressing only AKT2-S210N-S329N mutant channels (n = 22) differed significantly (Student''s t test, p < 4e-05) from wild-type plants (n = 20) in the height of the main inflorescent stalk (B) and fresh weight (C). At later time points, these differences decrease.²⁵Open in a separate windowFigure 3The mutant AKT2-K197R channel is inward-rectifying. Steady-state current-voltage characteristics measured at the end of activation voltage steps. Currents were normalized to the current values measured at −145 mV in 10 mM K⁺ and are shown as means ± SD (n = 6).Open in a separate windowFigure 4Minimal model for AKT2 gating-mode regulation. To switch AKT2 from an inward-rectifying into a non-rectifying channel, at least two post-translational steps are postulated. (1) Phosphorylation at residues AKT2-S210 and AKT2-S329 (transitions [1]→[2] and [3]→[4]) and (2) a yet unknown modification that most likely involves the residue AKT2-K197 (transitions [1]→[3] and [2]→[4]). Only after both modifications will AKT2 allow the efflux of K⁺ (state [4]).     

The role of trimerization in the osmoregulated betaine transporter BetP

The osmoregulated betaine transporter BetP is a stable trimer. Structural studies have shown that individual protomers can adopt distinct transport conformations, implying a functional role for the trimeric state in transport, although the role of trimerization in regulation is not yet understood. We designed putative monomeric mutants by molecular-dynamics simulations and in silico alanine-scanning mutagenesis. Several mutants including BetP-W101A/T351A were monomeric in detergent as well as in the membrane, as shown by blue native gel electrophoresis, crosslinking and electron microscopy. This monomeric form retains the ability to accumulate betaine, but is no longer regulated by hyperosmotic shock.     

Mapping the organization of axis of motion selective features in human area MT using high-field fMRI

Functional magnetic resonance imaging (fMRI) at high magnetic fields has made it possible to investigate the columnar organization of the human brain in vivo with high degrees of accuracy and sensitivity. Until now, these results have been limited to the organization principles of early visual cortex (V1). While the middle temporal area (MT) has been the first identified extra-striate visual area shown to exhibit a columnar organization in monkeys, evidence of MT's columnar response properties and topographic layout in humans has remained elusive. Research using various approaches suggests similar response properties as in monkeys but failed to provide direct evidence for direction or axis of motion selectivity in human area MT. By combining state of the art pulse sequence design, high spatial resolution in all three dimensions (0.8 mm isotropic), optimized coil design, ultrahigh field magnets (7 Tesla) and novel high resolution cortical grid sampling analysis tools, we provide the first direct evidence for large-scale axis of motion selective feature organization in human area MT closely matching predictions from topographic columnar-level simulations.     

A comparison of the potency of trimedoxime and other currently available oximes to reactivate tabun-inhibited acetylcholinesterase and eliminate acute toxic effects of tabun

Tabun (O-ethyl-N,N-dimethyl phosphoramidocyanidate) belongs to highly toxic organophosphorus compounds misused as chemical warfare agents for military as well as terroristic purposes. It differs from other highly toxic organophosphates by its chemical structure and by the fact that tabun-inhibited acetylcholinesterase is extraordinarily difficult to reactivate. The potency of trimedoxime and other commonly used oximes (pralidoxime, obidoxime, the oxime HI-6) to reactivate tabun-inhibited acetylcholinesterase and to eliminate tabun-induced acute effects was evaluated using in vitro and in vivo methods. In vitro calculated kinetic parameters of reactivation of tabun-inhibited acetylcholinesterase from rat brain homogenate and in vivo determined percentage of reactivation of tabun-inhibited blood and tissue acetylcholinesterase in poisoned rats show that trimedoxime seems to be the most efficacious reactivator in the case of tabun poisonings. Trimedoxime was also found to be the most efficacious oxime in the elimination of acute lethal toxic effects in tabun-poisoned rats and mice. The oxime HI-6, so efficacious against soman, does not seem to be sufficiently effective oxime to reactivate tabun-inhibited acetylcholinesterase and to counteract acute lethal effects of tabun.     

Control of autoimmunity by "epitope theft"

We all possess T cells with autoaggressive potential. Knowledge of their regulation is crucial for elucidating pathogenetic pathways and designing effective treatments for autoimmune diseases. A novel mechanism of T-cell silencing--in an autoimmune model--has recently been identified and is termed "epitope theft". The "thieves" are naive CD8+ T cells, which apparently "steal" MHC-class-I-antigen complexes from antigen-presenting cells (APCs). The deprived APCs can no longer activate other potentially pathogenic naive CD8+ T cells that are specific for the same epitope. This phenomenon is a previously unrecognized antigen-specific mode of protection against autoimmunity.     

Evolutionary engineering of multiple-stress resistant Saccharomyces cerevisiae

Various selection procedures in chemostats and batch cultures were systematically tested for their efficiency to select for a multiple-stress resistance phenotype in Saccharomyces cerevisiae. To determine the relative stress resistance phenotypes, mutant populations harvested at different time points and randomly chosen clones from selected populations were grown in batch cultures and exposed to oxidative, freezing-thawing, high-temperature and ethanol stress. For this purpose, we developed a high-throughput procedure in 96-well plates combined with a most-probable-number assay. Among all chemostat and batch selection strategies tested, the best selection strategy to obtain highly improved multiple-stress-resistant yeast was found to be batch selection for freezing-thawing stress. The final mutant populations selected for this particular stress were not only significantly improved in freezing-thawing stress resistance, but also in other stress resistances. The best isolated clone from these populations exhibited 102-, 89-, 62-, and 1429-fold increased resistance to freezing-thawing, temperature, ethanol, and oxidative stress, respectively. General selection guidelines for improving multiple-stress resistance in S. cerevisiae are presented and discussed.     

Involvement of the p97-Ufd1-Npl4 complex in the regulated endoplasmic reticulum-associated degradation of inositol 1,4,5-trisphosphate receptors

Inositol 1,4,5-trisphosphate (IP(3)) receptors form tetrameric, IP(3)-gated channels in endoplasmic reticulum membranes that govern the release of Ca(2+) from this organelle. In response to activation of certain G protein-coupled receptors that persistently elevate IP(3) concentration, IP(3) receptors are ubiquitinated and degraded by the ubiquitin-proteasome pathway. IP(3) receptor ubiquitination is mediated by the ubiquitin-conjugating enzyme, (mam)Ubc7, a component of the endoplasmic reticulum-associated degradation pathway. However, the mechanism by which ubiquitinated IP(3) receptors are transferred to the proteasome is not known. Here, we examine this process and show in several mammalian cell types that the ATPase p97 associates with IP(3) receptors in response to hormonal stimuli that induce IP(3) receptor ubiquitination. To examine the functional relevance of the p97 interaction with IP(3) receptors, we stably and specifically reduced p97 protein levels by 62 +/- 3% in Rat-1 fibroblasts using RNA interference. In these cells, endothelin-1-induced IP(3) receptor degradation was markedly retarded and the accumulation of ubiquitinated IP(3) receptors was markedly enhanced. These effects were reversed by expression of exogenous p97. In addition, Ufd1 and Npl4, which complex with p97, also associated with IP(3) receptors upon hormonal stimulation. We conclude that the p97-Ufd1-Npl4 complex couples ubiquitinated IP(3) receptors to proteasomal degradation and, thus, plays a key role in IP(3) receptor processing. These data also establish that the p97-Ufd1-Npl4 complex mediates endoplasmic reticulum-associated degradation in mammalian cells.     

Iron-sulfur cluster proteins: electron transfer and beyond

Iron-sulfur clusters-containing proteins participate in many cellular processes, including crucial biological events like DNA synthesis and processing of dioxygen. In most iron-sulfur proteins, the clusters function as electron-transfer groups in mediating one-electron redox processes and as such they are integral components of respiratory and photosynthetic electron transfer chains and numerous redox enzymes involved in carbon, oxygen, hydrogen, sulfur and nitrogen metabolism. Recently, novel regulatory and enzymatic functions of these proteins have emerged. Iron-sulfur cluster proteins participate in the control of gene expression, oxygen/nitrogen sensing, control of labile iron pool and DNA damage recognition and repair. Their role in cellular response to oxidative stress and as a source of free iron ions is also discussed.     

Inactivation and Disassembly of the Anaphase-Promoting Complex during Human Cytomegalovirus Infection Is Associated with Degradation of the APC5 and APC4 Subunits and Does Not Require UL97-Mediated Phosphorylation of Cdh1

Infection of quiescent cells by human cytomegalovirus (HCMV) elicits severe cell cycle deregulation, resulting in a G₁/S arrest, which can be partly attributed to the inactivation of the anaphase-promoting complex (APC). As we previously reported, the premature phosphorylation of its coactivator Cdh1 and/or the dissociation of the core complex can account for the inactivation. We have expanded on these results and further delineated the key components required for disabling the APC during HCMV infection. The viral protein kinase UL97 was hypothesized to phosphorylate Cdh1, and consistent with this, phosphatase assays utilizing a virus with a UL97 deletion mutation (ΔUL97 virus) indicated that Cdh1 is hypophosphorylated at early times in the infection. Mass spectrometry analysis demonstrated that UL97 can phosphorylate Cdh1 in vitro, and the majority of the sites identified correlated with previously characterized cyclin-dependent kinase (Cdk) consensus sites. Analysis of the APC core complex during ΔUL97 virus infection showed APC dissociation occurring at the same time as during infection with wild-type virus, suggesting that the UL97-mediated phosphorylation of Cdh1 is not required for this to occur. Further investigation of the APC subunits showed a proteasome-dependent loss of the APC5 and APC4 subunits that was temporally associated with the disassembly of the APC. Immediate early viral gene expression was not sufficient for the degradation of APC4 and APC5, indicating that a viral early gene product(s), possibly in association with a de novo-synthesized cellular protein(s), is involved.Human cytomegalovirus (HCMV), a highly prevalent β-herpesvirus, can cause serious birth defects and disease in immunocompromised individuals, and it may be associated with cancer and cardiovascular disease (53). Viral gene expression is temporally regulated and is dependent on many cellular factors for a productive infection. Immediate early (IE) genes are expressed by 2 h postinfection (p.i.) and transactivate the early genes required for viral DNA replication. The expression of the late genes, which encode proteins involved in virion maturation and egress, is dependent on viral DNA replication.The virus has adopted different strategies for altering the cellular environment to make it more conducive to productive infection, including the stimulation of host cell DNA replication pathways, cell cycle deregulation and arrest, immune evasion, and inhibition of apoptosis (53). Although HCMV encodes its own DNA polymerase, it is dependent on other cellular resources for DNA replication. Infection of quiescent cells induces passage toward S phase such that the host cell is stimulated to generate proteins and DNA precursors necessary for genome replication; however, entry into S phase and cellular DNA replication are subsequently blocked and the cell arrests in G₁/S (1, 10, 11, 14, 30, 45). Cellular resources are thereby presumably free to be efficiently utilized for viral replication. Cell cycle arrest by HCMV is achieved in part through the misregulation of several cell cycle proteins, including the phosphorylation and accumulation of the Rb family pocket proteins, upregulation of cyclins E and B and their associated kinase activities, inhibition of cyclin A expression, stabilization of p53, and accumulation of Cdc6 and geminin, which inhibits licensing of the cellular origins of DNA replication (8, 17, 30, 49, 54, 65). Some of these cell cycle defects can be attributed to a deregulation of the anaphase-promoting complex (APC) (8, 72, 79, 80), an E3 ubiquitin ligase that is responsible for the timely degradation of cell cycle proteins and mitotic cyclins to promote cycle progression from mitosis through G₁ to S phase (58, 74). As the APC also appears to be a common target among other viruses, including the chicken anemia virus, adenoviruses, and poxviruses (23, 36, 52, 70), understanding the mechanisms leading to its inactivation during viral infection has been of great interest.As we have previously reported, multiple mechanisms may be involved in disabling the APC during HCMV infection (72), which is not surprising given the complexity of its structure and regulation (for a review, see references 58 and 74). The APC is a large multisubunit complex consisting of at least 11 conserved core subunits, as well as other species-specific subunits. In metazoans, the APC2 and APC11 subunits form the catalytic core, and along with APC10, provide the platform for binding the E2 ubiquitin-conjugating enzyme. Each of the APC3, APC8, APC6, and APC7 subunits contain multiple copies of the tetratricopeptide repeat (TPR) motif and together make up the TPR subcomplex, which provides a platform of protein interaction surfaces for binding the coactivators (i.e., Cdh1 and Cdc20) and various substrates. These two subcomplexes are bridged by the large scaffolding subunit APC1, with the TPR subcomplex tethered to APC1 through APC4 and APC5. The binding between APC1, APC4, APC5, and APC8 is also interdependent, such that the loss of one subunit decreases the association of the other three (71).The APC is activated by either of its coactivators, Cdh1 or Cdc20, which also function in recruiting specific substrates to the APC during different phases of the cell cycle. The phosphorylation of several APC subunits at the onset of mitosis, including APC1 and the TPR subunits, by cyclin B/cyclin-dependent kinase 1 (Cdk1) and Plk1 allows the binding of Cdc20 and subsequent activation of the APC (APC^Cdc20) (19, 37), whereas the binding and activation of the complex by Cdh1 is inhibited through its phosphorylation by cyclin B/Cdk1 (9, 29, 38, 83). As cells pass the spindle assembly checkpoint, APC^Cdc20 ubiquitinates securin (to allow for sister chromatid separation) and cyclin B for degradation by the proteasome (42, 67). The subsequent inactivation of Cdk1 and activation of mitotic phosphatases during late anaphase relieves the inhibitory phosphorylation on Cdh1, presumably by Cdc14 (6, 38, 44), which then allows Cdh1 to bind and activate the APC (APC^Cdh1). APC^Cdh1 ubiquitinates Cdc20 and mitotic cyclins for degradation to facilitate mitotic exit and maintains their low levels, along with S-phase regulators (e.g., Cdc6, geminin, etc.), during G₁ (16, 50, 59, 63). The inactivation of APC^Cdh1 as cells enter S phase may be mediated in part through the phosphorylation of Cdh1 by cyclin A/Cdk2 (46) and Cdh1 binding to the inhibitor Emi1 (25). The inactivation of Cdh1 by phosphorylation has been shown in all organisms studied thus far (e.g., yeast, Drosophila, plants, mammals, etc.), and mutants mimicking constitutively phosphorylated Cdh1 on Cdk consensus sites can neither bind nor activate the APC in vivo or in vitro (9, 29, 38, 69, 83).During HCMV infection of fibroblasts in G₀/G₁, however, Cdh1 becomes prematurely phosphorylated in a Cdk-independent manner and no longer associates with the APC (72). This dissociation does not appear to be due to an overexpression of Emi1 (79). Cdc20 also can no longer associate with the APC (79), suggesting a defect in the APC core. We have further shown that the APC core complex disassembles during the infection, with the TPR subunits (i.e., APC3, APC7, and APC8) and APC10 localizing to the cytosol, while APC1 remains nuclear (72). Interestingly, both the phosphorylation of Cdh1 and the dissociation of the APC occur at similar times during HCMV infection. Although either of these mechanisms could render the APC inactive, it was unclear whether these processes are linked or represent independent (or redundant) pathways. The causative factor(s) in mediating these events and the question of whether such a factor(s) was of cellular or viral origin also remained unresolved.On the basis of the results of several recent studies (26, 32, 62), the viral protein kinase UL97 emerged as a likely candidate for involvement in the phosphorylation of Cdh1. Conserved among herpesviruses, UL97 functions in viral genome replication (7, 32, 81) and in nuclear egress of viral capsids (21, 39, 48). UL97 is present in the tegument of the virus particle (76) and is also expressed de novo with early kinetics (i.e., detectable by 5 h p.i. by Western blot assay), with increased expression at later times of the infection (51, 76, 77). UL97 is a serine/threonine (S/T) protein kinase (22), and recent studies have further characterized it as a Cdkl mimic, with predicted structural similarity to Cdk2 (64) and common substrates. UL97 has been shown to phosphorylate in vitro nuclear lamin A/C (21), the carboxyl-terminal domain of RNA polymerase II (5), the translation elongation factor 1δ (EF1δ) (33), and Rb (26, 62) on sites targeted by Cdks, and there is considerable evidence that UL97 phosphorylates lamin A/C, EF1δ, and Rb on these sites in infected cells as well (21, 26, 33, 62). Given that cyclin A/Cdk2 and cyclin B/Cdk1 complexes normally phosphorylate Cdh1, thus preventing its association with the APC, we hypothesized that UL97 phosphorylates Cdh1 during HCMV infection.In the present study, we provide further mechanistic details of the events and players involved in inactivating the APC during HCMV infection. Evidence that UL97 is the viral factor mediating the phosphorylation of Cdh1 was obtained. However, APC disassembly still occurred at similar times in ΔUL97 and wild-type virus infections, indicating that UL97-mediated phosphorylation of Cdh1 is not required for this event. The inactivation of the APC core complex is further attributed to the loss of the APC5 and APC4 subunits early during the infection. The degradation of these subunits is proteasome dependent and requires de novo synthesis of viral early or cellular proteins. While the primary mechanism of inactivation appears to be the dissociation of the complex and the targeted loss of APC5 and APC4, phosphorylation of Cdh1 may provide a small kinetic advantage and backup mechanism for disabling the APC.