Publications by authors named "Americo T Ranzani"
Vital organismal processes, including development, differentiation and adaptation, involve altered gene expression. Although expression is frequently controlled at the transcriptional stage, various regulation mechanisms operate at downstream levels. Here, we leverage the photoreceptor NmPAL to optogenetically induce RNA refolding and the translation of bacterial mRNAs.
View Article and Find Full Text PDFBacteria must constantly probe their environment for rapid adaptation, a crucial need most frequently served by two-component systems (TCS). As one component, sensor histidine kinases (SHK) control the phosphorylation of the second component, the response regulator (RR). Downstream responses hinge on RR phosphorylation and can be highly stringent, acute, and sensitive because SHKs commonly exert both kinase and phosphatase activity.
View Article and Find Full Text PDFBy applying sensory photoreceptors, optogenetics realizes the light-dependent control of cellular events and state. Given reversibility, noninvasiveness, and exquisite spatiotemporal precision, optogenetic approaches enable innovative use cases in cell biology, synthetic biology, and biotechnology. In this chapter, we detail the implementation of the pREDusk, pREDawn, pCrepusculo, and pAurora optogenetic circuits for controlling bacterial gene expression by red and blue light, respectively.
View Article and Find Full Text PDFThe regulation of gene expression by light enables the versatile, spatiotemporal manipulation of biological function in bacterial and mammalian cells. Optoribogenetics extends this principle by molecular RNA devices acting on the RNA level whose functions are controlled by the photoinduced interaction of a light-oxygen-voltage photoreceptor with cognate RNA aptamers. Here light-responsive ribozymes, denoted optozymes, which undergo light-dependent self-cleavage and thereby control gene expression are described.
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- * The pCrepusculo and pAurora systems were developed to respectively downregulate and upregulate bacterial gene expression via blue light, and they work as compact plasmids with minimal background activity.
- * By combining PAL's light-dependent RNA control with other optogenetic systems, more complex gene regulation can be achieved, exemplified by the pEnumbra setup, which regulates gene expression based on the intensity of blue light.
In optogenetics, as in nature, sensory photoreceptors serve to control cellular processes by light. Bacteriophytochrome (BphP) photoreceptors sense red and far-red light via a biliverdin chromophore and, in response, cycle between the spectroscopically, structurally, and functionally distinct Pr and Pfr states. BphPs commonly belong to two-component systems that control the phosphorylation of cognate response regulators and downstream gene expression through histidine kinase modules.
View Article and Find Full Text PDFIn nature as in biotechnology, light-oxygen-voltage photoreceptors perceive blue light to elicit spatiotemporally defined cellular responses. Photon absorption drives thioadduct formation between a conserved cysteine and the flavin chromophore. An equally conserved, proximal glutamine processes the resultant flavin protonation into downstream hydrogen-bond rearrangements.
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- Chagas disease lacks effective drug treatments, creating a significant medical need for better options.
- A large-scale screening initiative identified trypanocidal compounds assembled in the GSK Chagas Box, leading to the discovery of potent inhibitors for a crucial enzyme in the parasite.
- The study revealed the crystal structures of the enzyme bound to inhibitors, paving the way for further development of targeted treatments.
Ubiquitin-conjugating enzymes (E2) enable protein ubiquitination by conjugating ubiquitin to their catalytic cysteine for subsequent transfer to a target lysine side chain. Deprotonation of the incoming lysine enables its nucleophilicity, but determinants of lysine activation remain poorly understood. We report a novel pathogenic mutation in the E2 UBE2A, identified in two brothers with mild intellectual disability.
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- Chagas disease is caused by a parasite that lacks effective treatment options, prompting research into new metabolic targets like the malic enzyme (ME).
- Two types of malic enzyme isoforms (cytosolic and mitochondrial) help produce NADPH, which is crucial for various cellular processes.
- High-throughput screening of 30,000 compounds identified effective inhibitors, particularly from the sulfonamide group, which significantly target the cytosolic isoform and show potential to combat the parasite.
Article Synopsis
- Glucose-6-phosphate dehydrogenase (G6PDH) is an enzyme that converts glucose-6-phosphate to 6-phospho-gluconolactone, producing NADPH in the process.
- In solution, G6PDH acts as dimers and tetramers, making it difficult to compare their kinetics due to the preference for dimers in low enzyme concentrations.
- The study introduces two G6PDH mutants: one that stabilizes tetramers through disulfide bonds and another that prevents dimer formation, revealing the tetramer as the most active enzyme form.
Article Synopsis
- G6PDH is crucial for providing NADPH in cells and is targeted for drug development against Chagas disease caused by Trypanosoma cruzi.
- Existing inhibitors from steroidal compounds can affect both the parasite and human G6PDH, leading to potential side effects.
- New classes of inhibitors, specifically thienopyrimidine and quinazolinone derivatives, have been identified as more selective options for targeting the parasite without unwanted effects on human enzymes.
To shed more light on the molecular requirements for recognition of thyroid response elements (TREs) by thyroid receptors (TRs), we compared the specific aspects of DNA TRE recognition by different TR constructs. Using fluorescence anisotropy, we performed a detailed and hierarchical study of TR-TRE binding. This was done by comparing the binding affinities of three different TR constructs for four different TRE DNA elements, including palindromic sequences and direct repeats (F2, PAL, DR-1, and DR-4) as well as their interactions with nonspecific DNA sequences.
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