Signal transduction typically begins by ligand-dependent activation of a concomitant partner which is otherwise in its resting state. However, in cases where signal activation is constitutive by default, the mechanism of regulation is unknown. The Arabidopsis thaliana heterotrimeric Gα protein self-activates without accessory proteins, and is kept in its resting state by the negative regulator, AtRGS1 (Regulator of G protein Signaling 1), which is the prototype of a seven transmembrane receptor fused with an RGS domain. Endocytosis of AtRGS1 by ligand-dependent endocytosis physically uncouples the GTPase accelerating activity of AtRGS1 from the Gα protein, permitting sustained activation. Phosphorylation of AtRGS1 by AtWNK8 kinase causes AtRGS1 endocytosis, required both for G protein-mediated sugar signaling and cell proliferation. In animals, receptor endocytosis results in signal desensitization, whereas in plants, endocytosis results in signal activation. These findings reveal how different organisms rearrange a regulatory system to result in opposite outcomes using similar phosphorylation-dependent endocytosis.
Cellular senescence can modulate various pathologies and is associated with irreparable DNA double-strand breaks (IrrDSBs). Extracellular senescence metabolomes (ESMs) were generated from fibroblasts rendered senescent by proliferative exhaustion (PEsen) or 20 Gy of γ rays (IrrDSBsen) and compared with those of young proliferating cells, confluent cells, quiescent cells, and cells exposed to repairable levels of DNA damage to identify novel noninvasive markers of senescent cells. ESMs of PEsen and IrrDSBsen overlapped and showed increased levels of citrate, molecules involved in oxidative stress, a sterol, monohydroxylipids, tryptophan metabolism, phospholipid, and nucleotide catabolism, as well as reduced levels of dipeptides containing branched chain amino acids. The ESM overlaps with the aging and disease body fluid metabolomes, supporting their utility in the noninvasive detection of human senescent cells in vivo and by implication the detection of a variety of human pathologies. Intracellular metabolites of senescent cells showed a relative increase in glycolysis, gluconeogenesis, the pentose-phosphate pathway, and, consistent with this, pyruvate dehydrogenase kinase transcripts. In contrast, tricarboxylic acid cycle enzyme transcript levels were unchanged and their metabolites were depleted. These results are surprising because glycolysis antagonizes senescence entry but are consistent with established senescent cells entering a state of low oxidative stress.
Animal heterotrimeric G proteins are activated by guanine nucleotide exchange factors (GEF), typically seven transmembrane receptors that trigger GDP release and subsequent GTP binding. In contrast, the Arabidopsis thaliana G protein (AtGPA1) rapidly activates itself without a GEF and is instead regulated by a seven transmembrane Regulator of G protein Signaling (7TM-RGS) protein that promotes GTP hydrolysis to reset the inactive (GDP-bound) state. It is not known if this unusual activation is a major and constraining part of the evolutionary history of G signaling in eukaryotes. In particular, it is not known if this is an ancestral form or if this mechanism is maintained, and therefore constrained, within the plant kingdom. To determine if this mode of signal regulation is conserved throughout the plant kingdom, we analyzed available plant genomes for G protein signaling components, and we purified individually the plant components encoded in an informative set of plant genomes in order to determine their activation properties in vitro. While the subunits of the heterotrimeric G protein complex are encoded in vascular plant genomes, the 7TM-RGS genes were lost in all investigated grasses. Despite the absence of a Gα-inactivating protein in grasses, all vascular plant Gα proteins examined rapidly released GDP without a receptor and slowly hydrolyzed GTP, indicating that these Gα are self-activating. We showed further that a single amino acid substitution found naturally in grass Gα proteins reduced the Gα-RGS interaction, and this amino acid substitution occurred before the loss of the RGS gene in the grass lineage. Like grasses, non-vascular plants also appear to lack RGS proteins. However, unlike grasses, one representative non-vascular plant Gα showed rapid GTP hydrolysis, likely compensating for the loss of the RGS gene. Our findings, the loss of a regulatory gene and the retention of the “self-activating” trait, indicate the existence of divergent Gα regulatory mechanisms in the plant kingdom. In the grasses, purifying selection on the regulatory gene was lost after the physical decoupling of the RGS protein and its cognate Gα partner. More broadly these findings show extreme divergence in Gα activation and regulation that played a critical role in the evolution of G protein signaling pathways.
The C-terminal repeat domain (CTD) of the largest subunit of RNA polymerase II is composed of tandem heptad repeats with consensus sequence Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7. In yeast, this heptad sequence is repeated about 26 times, and it becomes hyperphosphorylated during transcription predominantly at serines 2 and 5. A network of kinases and phosphatases combine to determine the CTD phosphorylation pattern. We sought to determine the positional specificity of phosphorylation by yeast CTD kinase-I (CTDK-I), an enzyme implicated in various nuclear processes including elongation and pre-mRNA 3′-end formation. Toward this end, we characterized monoclonal antibodies commonly employed to study CTD phosphorylation patterns and found that the H5 monoclonal antibody reacts with CTD species phosphorylated at Ser2 and/or Ser5. We therefore used antibody-independent methods to study CTDK-I, and we found that CTDK-I phosphorylates Ser5 of the CTD if the CTD substrate is either unphosphorylated or prephosphorylated at Ser2. When Ser5 is already phosphorylated, CTDK-I phosphorylates Ser2 of the CTD. We also observed that CTDK-I efficiently generates doubly phosphorylated CTD repeats; CTD substrates that already contain Ser2-PO 4 or Ser5-PO 4 are more readily phosphorylated by CTDK-I than unphosphorylated CTD substrates.The C-terminal domain (CTD) 1 of the largest subunit (Rpb1p) of budding yeast RNA polymerase II (RNAPII) is composed of about 26 tandem repeats of Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7 (YSPTSPS). Considering that five of seven of these consensus amino acids are potential phosphoacceptors, it is not surprising that this domain is a substrate for phosphorylation. The extent of CTD phosphorylation correlates with the activity of the polymerase: initiating polymerases have unphosphorylated CTDs, whereas CTD hyperphosphorylation is associated with elongation (1-6). Phosphorylation also affects the protein-protein interactions between the CTD and binding partners such as mRNA processing factors (reviewed in Ref. 7).In budding yeast, phosphorylation occurs predominantly at serines 2 and 5 of the CTD, and Ser2-PO 4 and Ser5-PO 4 are thought to have separate and essential roles. Substitution of either * This work was supported by National Institutes of Health Grant GM40505 (to A. L. G.).∥To whom correspondence should be addressed. ; E-mail: E-mail: arno@biochem.duke.edu. 1 The abbreviations used are: CTD, C-terminal domain of RNA polymerase II large subunit; RNAPII, RNA polymerase II; GST, glutathione S-transferase; RU, resonance units; mAb, monoclonal antibody; ChIP, chromatin immunoprecipitation; PIC, preinitiation complex; HPLC, high pressure liquid chromatography; P-TEFb, positive transcription elongation factor. NIH Public Access NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptSer2 or Ser5 with alanine or glutamate in each repeat is lethal in yeast (8), and suppressors of Ser2 mutations do not suppress the lethal phenotype of Ser5 mutation (9). Phosphorylation of Ser5 of the CTD ...
In animals, heterotrimeric guanine nucleotide–binding protein (G protein) signaling is initiated by G protein–coupled receptors (GPCRs), which activate G protein α subunits; however, the plant Arabidopsis thaliana lacks canonical GPCRs, and its G protein α subunit (AtGPA1) is self-activating. To investigate how AtGPA1 becomes activated, we determined its crystal structure. AtGPA1 is structurally similar to animal G protein α subunits, but our crystallographic and biophysical studies revealed that it had distinct properties. Notably, the helical domain of AtGPA1 displayed pronounced intrinsic disorder and a tendency to disengage from the Ras domain of the protein. Domain substitution experiments showed that the helical domain of AtGPA1 was necessary for self-activation and sufficient to confer self-activation to an animal G protein α subunit. These findings reveal the structural basis for a mechanism for G protein activation in Arabidopsis that is distinct from the well-established mechanism found in animals.
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