A bridge between the aminoacylation and editing domains of leucyl-tRNA synthetase is crucial for its synthetic activity

Biallelic variants in LARS1 induce steatosis in developing zebrafish liver via enhanced autophagy

BACKGROUND

Biallelic pathogenic variants of LARS1 cause infantile liver failure syndrome type 1 (ILFS1), which is characterized by acute hepatic failure with steatosis in infants. LARS functions as a protein associated with mTORC1 and plays a crucial role in amino acid-triggered mTORC1 activation and regulation of autophagy. A previous study demonstrated that larsb-knockout zebrafish exhibit conditions resembling ILFS. However, a comprehensive analysis of larsb-knockout zebrafish has not yet been performed because of early mortality.

METHODS

We generated a long-term viable zebrafish model carrying a LARS1 variant identified in an ILFS1 patient (larsb-I451F zebrafish) and analyzed the pathogenesis of the affected liver of ILFS1.

RESULTS

Hepatic dysfunction is most prominent in ILFS1 patients during infancy; correspondingly, the larsb-I451F zebrafish manifested hepatic anomalies during developmental stages. The larsb-I451F zebrafish demonstrates augmented lipid accumulation within the liver during autophagy activation. Inhibition of DGAT1, which converts fatty acids to triacylglycerols, improved lipid droplets in the liver of larsb-I451F zebrafish. Notably, treatment with an autophagy inhibitor ameliorated hepatic lipid accumulation in this model.

CONCLUSIONS

Our findings suggested that enhanced autophagy caused by biallelic LARS1 variants contributes to ILFS1-associated hepatic dysfunction. Furthermore, the larsb-I451F zebrafish model, which has a prolonged survival rate compared with the larsb-knockout model, highlights its potential utility as a tool for investigating the pathophysiology of ILFS1-associated liver dysfunction.

Aminoacyl tRNA Synthetases: Implications of Structural Biology in Drug Development against Trypanosomatid Parasites

The ensemble of aminoacyl tRNA synthetases is regarded as a key component of the protein translation machinery. With the progressive increase in structure-based studies on tRNA synthetase-ligand complexes, the detailed picture of these enzymes is becoming clear. Having known their critical role in deciphering the genetic code in a living system, they have always been chosen as one of the important targets for development of antimicrobial drugs. Later on, the role of aminoacyl tRNA synthetases (aaRSs) on the survivability of trypanosomatids has also been validated. It became evident through several gene knockout studies that targeting even one of these enzymes affected parasitic growth drastically. Such successful studies have inspired researchers to search for inhibitors that could specifically target trypanosomal aaRSs, and their never-ending efforts have provided fruitful results. Taking all such studies into consideration, these macromolecules of prime importance deserve further investigation for the development of drugs that cure spectrum of infections caused by trypanosomatids. In this review, we have compiled advancements of over a decade that have taken place in the pursuit of devising drugs by using trypanosomatid aaRSs as a major target of interest. Several of these inhibitors work on an exemplary low concentration range without posing any threat to the mammalian cells which is a very critical aspect of the drug discovery process. Advancements have been made in terms of using structural biology as an important tool to analyze the architecture of the trypanosomatids aaRSs and concoction of inhibitors with augmented specificities toward their targets. Some of the inhibitors that have been tested on other parasites successfully but their efficacy has so far not been validated against these trypanosomatids have also been appended.

Cytoplasmic isoleucyl tRNA synthetase as an attractive multistage antimalarial drug target

Development of antimalarial compounds into clinical candidates remains costly and arduous without detailed knowledge of the target. As resistance increases and treatment options at various stages of disease are limited, it is critical to identify multistage drug targets that are readily interrogated in biochemical assays. Whole-genome sequencing of 18 parasite clones evolved using thienopyrimidine compounds with submicromolar, rapid-killing, pan-life cycle antiparasitic activity showed that all had acquired mutations in the P. falciparum cytoplasmic isoleucyl tRNA synthetase (cIRS). Engineering two of the mutations into drug-naïve parasites recapitulated the resistance phenotype, and parasites with conditional knockdowns of cIRS became hypersensitive to two thienopyrimidines. Purified recombinant P. vivax cIRS inhibition, cross-resistance, and biochemical assays indicated a noncompetitive, allosteric binding site that is distinct from that of known cIRS inhibitors mupirocin and reveromycin A. Our data show that Plasmodium cIRS is an important chemically and genetically validated target for next-generation medicines for malaria.

The tRNA identity landscape for aminoacylation and beyond

tRNAs are key partners in ribosome-dependent protein synthesis. This process is highly dependent on the fidelity of tRNA aminoacylation by aminoacyl-tRNA synthetases and relies primarily on sets of identities within tRNA molecules composed of determinants and antideterminants preventing mischarging by non-cognate synthetases. Such identity sets were discovered in the tRNAs of a few model organisms, and their properties were generalized as universal identity rules. Since then, the panel of identity elements governing the accuracy of tRNA aminoacylation has expanded considerably, but the increasing number of reported functional idiosyncrasies has led to some confusion. In parallel, the description of other processes involving tRNAs, often well beyond aminoacylation, has progressed considerably, greatly expanding their interactome and uncovering multiple novel identities on the same tRNA molecule. This review highlights key findings on the mechanistics and evolution of tRNA and tRNA-like identities. In addition, new methods and their results for searching sets of multiple identities on a single tRNA are discussed. Taken together, this knowledge shows that a comprehensive understanding of the functional role of individual and collective nucleotide identity sets in tRNA molecules is needed for medical, biotechnological and other applications.

A Novel Leucyl-tRNA Synthetase Inhibitor, MRX-6038, Expresses Anti-Mycobacterium abscessus Activity In Vitro and In Vivo

Therapeutic options for Mycobacterium abscessus infections are extremely limited, and new drugs are needed. The anti-M. abscessus activity of MRX-6038, a new leucyl-tRNA synthetase inhibitor, was evaluated in vitro and in vivo. Antimicrobial susceptibility testing was performed on 12 nontuberculosis mycobacteria (NTM) reference strains and 227 clinical NTM isolates. A minimum bactericidal concentration assay was conducted to distinguish the bactericidal versus bacteriostatic activity of MRX-6038. The synergy between MRX-6038 and 12 clinically important antibiotics was determined using a checkerboard assay. The activity of MRX-6038 against M. abscessus residing inside macrophages was also evaluated. Finally, the potency of MRX-6038 in vivo was determined in a neutropenic mouse model that mimicked a pulmonary M. abscessus infection. MRX-6038 exhibited high anti-M. abscessus activity against extracellular M. abscessus in culture, with a MIC₅₀ of 0.063 mg/L and a MIC₉₀ of 0.125 mg/L. Fifty percent of the activity was bactericidal, and fifty percent was bacteriostatic. A synergy between MRX-6038 and clarithromycin or azithromycin was found in 25% of strains. No antagonism was evident between MRX-6038 and 12 antibiotics commonly used to treat NTM infections. MRX-6038 also exhibited activity against intracellular NTM, which caused a significant reduction in the bacterial load in the lungs of M. abscessus-infected neutropenic mice. In conclusion, MRX-6038 was active against M. abscessusin vitro and in vivo, and it represents a potential candidate for incorporation into strategies by which M. abscessus infections are treated.

Molecular basis of the multifaceted functions of human leucyl-tRNA synthetase in protein synthesis and beyond

Human cytosolic leucyl-tRNA synthetase (hcLRS) is an essential and multifunctional enzyme. Its canonical function is to catalyze the covalent ligation of leucine to tRNA^Leu, and it may also hydrolyze mischarged tRNAs through an editing mechanism. Together with eight other aminoacyl-tRNA synthetases (AaRSs) and three auxiliary proteins, it forms a large multi-synthetase complex (MSC). Beyond its role in translation, hcLRS has an important moonlight function as a leucine sensor in the rapamycin complex 1 (mTORC1) pathway. Since this pathway is active in cancer development, hcLRS is a potential target for anti-tumor drug development. Moreover, LRS from pathogenic microbes are proven drug targets for developing antibiotics, which however should not inhibit hcLRS. Here we present the crystal structure of hcLRS at a 2.5 Å resolution, the first complete structure of a eukaryotic LRS, and analyze the binding of various compounds that target different sites of hcLRS. We also deduce the assembly mechanism of hcLRS into the MSC through reconstitution of the entire mega complex in vitro. Overall, our study provides the molecular basis for understanding both the multifaceted functions of hcLRS and for drug development targeting these functions.

Aminoacyl-tRNA synthetases in cell signaling

Aminoacyl-tRNA synthetases (ARSs) are a family of essential "housekeeping" enzymes ubiquitous in the three major domains of life. ARSs uniquely connect the essential minimal units of both major oligomer classes-the 3-nucleotide codons of oligonucleotides and the amino acids of proteins. They catalyze the esterification of amino acids to the 3'-end of cognate transfer RNAs (tRNAs) bearing the correct anticodon triplet to ensure accurate transfer of information from mRNA to protein according to the genetic code. As an essential translation factor responsible for the first biochemical reaction in protein biosynthesis, ARSs control protein production by catalyzing aminoacylation, and by editing of mischarged aminoacyl-tRNAs to maintain translational fidelity. In addition to their primary enzymatic activities, many ARSs have noncanonical functions unrelated to their catalytic activity in protein synthesis. Among the ARSs with "moonlighting" activities, several, including GluProRS (or EPRS), LeuRS, LysRS, SerRS, TyrRS, and TrpRS, exhibit cell signaling-related activities that sense environmental signals, regulate gene expression, and modulate cellular functions. ARS signaling functions generally depend on catalytically-inactive, appended domains not present in ancient enzyme forms, and are activated by stimulus-dependent post-translational modification. Activation often results in cellular re-localization and gain of new interacting partners. The newly formed ARS-bearing complexes conduct a host of signal transduction functions, including immune response, mTORC1 pathway signaling, and fibrogenic and angiogenic signaling, among others. Because noncanonical functions of ARSs in signal transduction are uncoupled from canonical aminoacylation functions, function-specific inhibitors can be developed, thus providing promising opportunities and therapeutic targets for treatment of human disease.

Severe Neonatal Manifestations of Infantile Liver Failure Syndrome Type 1 Caused by Cytosolic Leucine-tRNA Synthetase Deficiency

BACKGROUND

Deleterious mutations in cytosolic leucine-tRNA synthetase (LARS) cause infantile liver failure syndrome, type 1 (ILFS1), a recently recognized, rare autosomal recessive disorder (OMIM151350). Only six families with ILFS1 have been reported in the literature. Patients with ILFS1 are typically diagnosed between 5 and 24 months of age with failure to thrive, developmental delays, encephalopathy, microcytic anemia, and chronic liver dysfunction with recurrent exacerbations following childhood illnesses. Neonatal manifestations of this disorder have not been well documented.

CASE REPORT

We report a premature female newborn with intrauterine growth restriction, failure to thrive, congenital anemia, anasarca, and fulminant liver failure leading to lethal multiple organ failure. Liver failure in this infant was characterized by a disproportionate impairment of liver synthetic function, including severe coagulopathy and hypoalbuminemia without significant defects in liver detoxification or evidence of hepatocellular injury during early phase of the disease. Whole-exome sequencing of child-parent trio identified two inherited missense mutations in LARS in this patient. One, c.1292T>A; p.Val431Asp, has been reported in patients with ILFS1, while the other, c.725C>T; p.Pro242Leu, is novel. Both mutations involve amino acid residues in the highly conserved editing domain of LARS, are predicted to be functionally deleterious, and presumably contribute to the clinical manifestations in this patient.

CONCLUSION

This is the first case documenting neonatal manifestation of ILFS1, highlighting early, severe, and disproportionate defects in liver synthetic function. Timely diagnosis of ILFS1 is crucial to guide critical clinical management and improve outcomes of this rare and potentially life-threatening disorder.