Project description:BackgroundIn the eukaryotic cell the cAMP-dependent protein kinase (PKA) is a key enzyme in signal transduction and represents the main target of the second messenger cAMP. Here we describe the design, synthesis and characterisation of specifically tailored cAMP analogs which can be utilised as a tool for affinity enrichment and purification as well as for proteomics based analyses of cAMP binding proteins.ResultsTwo sets of chemical binders were developed based on the phosphorothioate derivatives of cAMP, Sp-cAMPS and Rp-cAMPS acting as cAMP-agonists and -antagonists, respectively. These compounds were tested via direct surface plasmon resonance (SPR) analyses for their binding properties to PKA R-subunits and holoenzyme. Furthermore, these analogs were used in an affinity purification approach to analyse their binding and elution properties for the enrichment and improvement of cAMP binding proteins exemplified by the PKA R-subunits. As determined by SPR, all tested Sp-analogs provide valuable tools for affinity chromatography. However, Sp-8-AEA-cAMPS displayed (i) superior enrichment properties while maintaining low unspecific binding to other proteins in crude cell lysates, (ii) allowing mild elution conditions and (iii) providing the capability to efficiently purify all four isoforms of active PKA R-subunit in milligram quantities within 8 h. In a chemical proteomics approach both sets of binders, Rp- and Sp-cAMPS derivatives, can be employed. Whereas Sp-8-AEA-cAMPS preferentially binds free R-subunit, Rp-AHDAA-cAMPS, displaying antagonist properties, not only binds to the free PKA R-subunits but also to the intact PKA holoenzyme both from recombinant and endogenous sources.ConclusionIn summary, all tested cAMP analogs were useful for their respective application as an affinity reagent which can enhance purification of cAMP binding proteins. Sp-8-AEA-cAMPS was considered the most efficient analog since Sp-8-AHA-cAMPS and Sp-2-AHA-cAMPS, demonstrated incomplete elution from the matrix, as well as retaining notable amounts of bound protein contaminants. Furthermore it could be demonstrated that an affinity resin based on Rp-8-AHDAA-cAMPS provides a valuable tool for chemical proteomics approaches.

Project description:Pyridoxal-5'-phosphate (vitamin B(6) ) is an essential cofactor for many important enzymatic reactions such as transamination and decarboxylation. African trypanosomes are unable to synthesise vitamin B(6) de novo and rely on uptake of B(6) vitamers such as pyridoxal and pyridoxamine from their hosts, which are subsequently phosphorylated by pyridoxal kinase (PdxK). A conditional null mutant of PdxK was generated in Trypanosoma brucei bloodstream forms showing that this enzyme is essential for growth of the parasite in vitro and for infectivity in mice. Activity of recombinant T. brucei PdxK was comparable to previously published work having a specific activity of 327 ± 13 mU mg(-1) and a K(m)(app) with respect to pyridoxal of 29.6 ± 3.9 µM. A coupled assay was developed demonstrating that the enzyme has equivalent catalytic efficiency with pyridoxal, pyridoxamine and pyridoxine, and that ginkgotoxin is an effective pseudo substrate. A high resolution structure of PdxK in complex with ATP revealed important structural differences with the human enzyme. These findings suggest that pyridoxal kinase is an essential and druggable target that could lead to much needed alternative treatments for this devastating disease.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:mTOR is a serine/threonine kinase with a crucial role in regulating fundamental cellular processes and is an attractive anticancer target. Multiple clinical trials of mTOR kinase inhibitors such as AZD2014 that suppress both mTORC1 and mTORC2 are ongoing, but their specificity and toxicity features remain a concern. We have developed an inducible kinase-dead D2338A mTOR mouse knock-in model and show that it is useful to study the kinase-independent function of mTOR and for assessing the off-target effects of mTOR kinase inhibitors. We found that while the mTOR KI mice in hematopoietic system displayed similar phenotypes to that of mTOR KO mice, they have significantly prolonged survival time than the KO mice. Whereas AZD2014 was mostly on-target in suppressing mTOR kinase activity, mimicking that seen in KI stem cells in transcriptome analysis, off-target genes in KI cells induced by AZD2014 including Ahnak2, Emp1, Lilrb4, Tpsb2, and Cma1 were detected. Our studies reveal kinase-independent function of mTOR in hematopoiesis and presents a mouse model for precisely assessing specificity of mTOR kinase inhibitors. Stringent test of drugs with such mouse models in the preclinical setting may provide useful information guiding the safety and efficacy of related clinical trials.

Project description:mTOR is a serine/threonine kinase with a crucial role in regulating fundamental cellular processes and is an attractive anticancer target. Multiple clinical trials of mTOR kinase inhibitors such as AZD2014 that suppress both mTORC1 and mTORC2 are ongoing, but their specificity and toxicity features remain a concern. We have developed an inducible kinase-dead D2338A mTOR mouse knock-in model and show that it is useful to study the kinase-independent function of mTOR and for assessing the off-target effects of mTOR kinase inhibitors. We found that while the mTOR KI mice in hematopoietic system displayed similar phenotypes to that of mTOR KO mice, they have significantly prolonged survival time than the KO mice. Whereas AZD2014 was mostly on-target in suppressing mTOR kinase activity, mimicking that seen in KI stem cells in transcriptome analysis, off-target genes in KI cells induced by AZD2014 including Ahnak2, Emp1, Lilrb4, Tpsb2, and Cma1 were detected. Our studies reveal kinase-independent function of mTOR in hematopoiesis and presents a mouse model for precisely assessing specificity of mTOR kinase inhibitors. Stringent test of drugs with such mouse models in the preclinical setting may provide useful information guiding the safety and efficacy of related clinical trials.

Project description:mTOR is a serine/threonine kinase with a crucial role in regulating fundamental cellular processes and is an attractive anticancer target. Multiple clinical trials of mTOR kinase inhibitors such as AZD2014 that suppress both mTORC1 and mTORC2 are ongoing, but their specificity and toxicity features remain a concern. We have developed an inducible kinase-dead D2338A mTOR mouse knock-in model and show that it is useful to study the kinase-independent function of mTOR and for assessing the off-target effects of mTOR kinase inhibitors. We found that while the mTOR KI mice in hematopoietic system displayed similar phenotypes to that of mTOR KO mice, they have significantly prolonged survival time than the KO mice. Whereas AZD2014 was mostly on-target in suppressing mTOR kinase activity, mimicking that seen in KI stem cells in transcriptome analysis, off-target genes in KI cells induced by AZD2014 including Ahnak2, Emp1, Lilrb4, Tpsb2, and Cma1 were detected. Our studies reveal kinase-independent function of mTOR in hematopoiesis and presents a mouse model for precisely assessing specificity of mTOR kinase inhibitors. Stringent test of drugs with such mouse models in the preclinical setting may provide useful information guiding the safety and efficacy of related clinical trials.

Project description:Therapeutic interventions targeting viral infections remain a significant challenge for both the medical and scientific communities. While specific antiviral agents have shown success as therapeutics, viral resistance inevitably develops, making many of these approaches ineffective. This inescapable obstacle warrants alternative approaches, such as the targeting of host cellular factors. Respiratory syncytial virus (RSV), the major respiratory pathogen of infants and children worldwide, causes respiratory tract infection ranging from mild upper respiratory tract symptoms to severe life-threatening lower respiratory tract disease. Despite the fact that the molecular biology of the virus, which was originally discovered in 1956, is well described, there is no vaccine or effective antiviral treatment against RSV infection. Here, we demonstrate that targeting host factors, specifically, mTOR signaling, reduces RSV protein production and generation of infectious progeny virus. Further, we show that this approach can be generalizable as inhibition of mTOR kinases reduces coronavirus gene expression, mRNA transcription and protein production. Overall, defining virus replication-dependent host functions may be an effective means to combat viral infections, particularly in the absence of antiviral drugs.

Project description:The mammalian target of rapamycin (mTOR) is a ubiquitously expressed serine/threonine kinase protein complex (mTORC1 or mTORC2) that orchestrates diverse functions ranging from embryonic development to aging. However, its brain tissue-specific roles remain less explored. Here, we have identified that the depletion of the mTOR gene in the mice striatum completely prevented the extrapyramidal motor side effects (catalepsy) induced by the dopamine 2 receptor (D2R) antagonist haloperidol, which is the most widely used typical antipsychotic drug. Conversely, a lack of striatal mTOR in mice did not affect catalepsy triggered by the dopamine 1 receptor (D1R) antagonist SCH23390. Along with the lack of cataleptic effects, the administration of haloperidol in mTOR mutants failed to increase striatal phosphorylation levels of ribosomal protein pS6 (S235/236) as seen in control animals. To confirm the observations of the genetic approach, we used a pharmacological method and determined that the mTORC1 inhibitor rapamycin has a profound influence upon post-synaptic D2R-dependent functions. We consistently found that pretreatment with rapamycin entirely prevented (in a time-dependent manner) the haloperidol-induced catalepsy, and pS6K (T389) and pS6 (S235/236) signaling upregulation, in wild-type mice. Collectively, our data indicate that striatal mTORC1 blockade may offer therapeutic benefits with regard to the prevention of D2R-dependent extrapyramidal motor side effects of haloperidol in psychiatric illness.

Project description:Autophagy is a cell-protective and degradative process that recycles damaged and long-lived cellular components. Cancer cells are thought to take advantage of autophagy to help them to cope with the stress of tumorigenesis; thus targeting autophagy is an attractive therapeutic approach. However, there are currently no specific inhibitors of autophagy. ULK1, a serine/threonine protein kinase, is essential for the initial stages of autophagy, and here we report that two compounds, MRT67307 and MRT68921, potently inhibit ULK1 and ULK2 in vitro and block autophagy in cells. Using a drug-resistant ULK1 mutant, we show that the autophagy-inhibiting capacity of the compounds is specifically through ULK1. ULK1 inhibition results in accumulation of stalled early autophagosomal structures, indicating a role for ULK1 in the maturation of autophagosomes as well as initiation.

Project description:Radiotherapy is routinely used as a neoadjuvant, adjuvant or palliative treatment in various cancers. There is significant variation in clinical response to radiotherapy with or without traditional chemotherapy. Patients with a good response to radiotherapy demonstrate better clinical outcomes universally across different cancers. The PI3K/AKT/mTOR pathway upregulation has been linked to radiotherapy resistance. We reviewed the current literature exploring the role of inhibiting targets along this pathway, in enhancing radiotherapy response. We identified several studies using in vitro cancer cell lines, in vivo tumour xenografts and a few Phase I/II clinical trials. Most of the current evidence in this area comes from glioblastoma multiforme, non-small cell lung cancer, head and neck cancer, colorectal cancer, and prostate cancer. The biological basis for radiosensitivity following pathway inhibition was through inhibited DNA double strand break repair, inhibited cell proliferation, enhanced apoptosis and autophagy as well as tumour microenvironment changes. Dual PI3K/mTOR inhibition consistently demonstrated radiosensitisation of all types of cancer cells. Single pathway component inhibitors and other inhibitor combinations yielded variable outcomes especially within early clinical trials. There is ample evidence from preclinical studies to suggest that direct pharmacological inhibition of the PI3K/AKT/mTOR pathway components can radiosensitise different types of cancer cells. We recommend that future in vitro and in vivo research in this field should focus on dual PI3K/mTOR inhibitors. Early clinical trials are needed to assess the feasibility and efficacy of these dual inhibitors in combination with radiotherapy in brain, lung, head and neck, breast, prostate and rectal cancer patients.