Demand For Protein Synthesis Research Articles

Targeting Ribosome Biogenesis for Cancer Therapy with Oral Platinum Complexes.

Cancer cells often upregulate ribosome biogenesis to meet increased protein synthesis demands for rapid proliferation; therefore, targeting ribosome biogenesis has emerged as a promising cancer therapeutic strategy. Herein, we introduce two Pt complexes, ataluren monosubstituted platinum(IV) (SPA, formula: c,c,t,-[Pt(NH3)2Cl2(OH)(C15H8FN2O3)], where C15H8FN2O3 = ataluren) and ataluren bisubstituted platinum(IV) complex (DPA, formula: c,c,t,-[Pt(NH3)2Cl2(C15H8FN2O3)2], where C15H8FN2O3 = ataluren), which effectively suppress ribosome biogenesis by inhibiting 47s pre-RNA expression. Furthermore, SPA and DPA induce nucleolar stress by dispersing nucleolar protein NPM1, ultimately inhibiting protein generation in tumor cells. More importantly, DPA exhibits superior cytotoxicity to various cancer cells and in vivo antitumor efficacy compared to cisplatin, with lower systemic toxicity. Notably, in clinically relevant models, including orthotopic hepatic tumor-bearing mice and patient-derived bladder cancer organoids, DPA outperforms cisplatin significantly, with the added benefit of oral administration, enhancing clinical feasibility. To our knowledge, DPA emerges as the pioneering Pt(IV) agent targeting the ribosome, providing new insights for designing next-generation metal-based therapeutics.

Protein quality malnutrition.

Protein quality refers to the evaluation of a food or a diet based on its amino acid composition, protein digestibility, and protein bioavailability. When these parameters are specified, either through direct measurement or estimation, the amino acids provided by the diet are compared to those required by a healthy individual, and based on this comparison, an adequacy ratio or score is assigned. Two widely used protein quality scoring systems are the protein digestibility-corrected amino acid score (PDCAAS) and the digestible indispensable amino acid score (DIAAS), neither of which account for the dietary source of the protein. In malnourished children, metabolic adaptations reduce the endogenous availability of amino acids and increase the demand for protein synthesis. These increased amino acid requirements are primarily driven by the presence of acute infection and the need for tissue accretion. This review examines two large clinical feeding trials involving moderately malnourished children, where dietary protein quality was carefully measured. The finding s suggest that protein quality scores alone do not reliably predict weight gain or recovery in these children and that consuming milk protein provides distinct advantages over vegetable-based proteins.

A complex array of factors regulate the activity of Arabidopsis thaliana δ1 -pyrroline-5-carboxylate synthetase isoenzymes to ensure their specific role in plant cell metabolism.

The first and committed step in proline synthesis from glutamate is catalyzed by δ1 -pyrroline-5-carboxylate synthetase (P5CS). Two P5CS genes have been found in most angiosperms, one constitutively expressed to satisfy proline demand for protein synthesis, the other stress-induced. Despite the number of papers to investigate regulation at the transcriptional level, to date, the properties of the enzymes have been subjected to limited study. The isolation of Arabidopsis thaliana P5CS isoenzymes was achieved through heterologous expression and affinity purification. The two proteins were characterized with respect to kinetic and biochemical properties. AtP5CS2 showed KM values in the micro- to millimolar range, and its activity was inhibited by NADP+ , ADP and proline, and by glutamine and arginine at high levels. Mg2+ ions were required for activity, which was further stimulated by K+ and other cations. AtP5CS1 displayed positive cooperativity with glutamate and was almost insensitive to inhibition by proline. In the presence of physiological, nonsaturating concentrations of glutamate, proline was slightly stimulatory, and glutamine strongly increased the catalytic rate. Data suggest that the activity of AtP5CS isoenzymes is differentially regulated by a complex array of factors including the concentrations of proline, glutamate, glutamine, monovalent cationsand pyridine dinucleotides.

Targeting Endothelial PERK-DLL4 Axis to Enhance Hematopoietic Stem Cell and Lymphoid Progenitor Regeneration

Despite our current information on hundreds of genes implicated in hematopoietic stem cells (HSC) biology, major gaps still exist in our understanding of HSC physiology and their regeneration mechanism under disease and stress conditions, hindering the development of strategies to enhance HSC regeneration. HSCs reside in a tightly controlled bone marrow HSC niche that regulates and maintains hematopoietic homeostasis. HSC niche is composed of a heterogeneous population of specialized stroma cells. Among these, the endothelial cells and the perivascular stroma cells provide critical pro-hematopoietic factors to support HSC pool and committed lineage progenitors particularly lymphoid progenitors. In addition, evidence suggests that endothelium-expressing Notch ligand may promote Notch-dependent long-term HSC proliferation. Recent single cell transcriptome profiling revealed that Delta-like 4 (DLL4) is expressed by the vascular endothelial cells at a higher level than other Notch ligands while its expression down-regulates in response to myeloablation. However, the molecular mechanism regulating the dynamic DLL4 expression during hematopoietic regeneration in response to myeloablative stimuli is unknown. Unfolded protein response (UPR) (also known as endoplasmic reticulum stress, ER stress) has been increasingly recognized as crucial for HSC maintenance. During hematopoietic regeneration, UPR is critical for meeting the increased demand for protein synthesis required for rapid cellular proliferation and for adapting to pathological conditions such as increased levels of reactive oxygen species following irradiation or chemotherapy. Unlike HSCs, how HSC niche endothelial cells deal with redox imbalance and higher requirements of vessel regeneration to regulate stress hematopoietic regeneration is not clear. In this study, using genetically engineered mouse models, we examined the dynamic expression and function of PERK, one arm of UPR, and its potential downstream target, Dll4, during the stress hematopoiesis triggered by transplantation. We found that PERK is activated in the mouse bone marrow endothelial cells following irradiation. Ablation of endothelial Perk in mice (referred as Perk iΔEC mice) promoted post-transplantation immediate recovery of blood cells derived from wild type donor mice and enhanced HSC and lymphoid progenitor regeneration with the expansion of B lineage progenitors including pre-proB, pro-B, and pre-B cells. In addition, by whole-mount immunostaining and intravital microscopy, we found that endothelial Perk deletion restrained disorganized angiogenesis and vascular leakage provoked by irradiation. Although irradiation itself had no effect on endothelial Dll4, Perk ablation markedly increased endothelial Dll4 expression. We found that Dll4 is essential for the post-irradiation HSC and lymphoid progenitor rejuvenation as ablation of endothelial Dll4 in mice (referred as Dll4 iΔEC mice) led to impaired short-term and long-term hematopoietic regeneration and markedly decreased wild type donor derived peripheral B cell and lymphoid progenitor recovery. We found that endothelial Dll4 is required for HSC quiescence maintenance, HSC niche retention and HSC self-renewal. Further, ablation of endothelial Dll4 led to disorganized bone marrow angiogenesis and increased marrow vascular leakage. Finally, we showed that deletion of Dll4 in Perk iΔEC mice completely abrogated the increased numbers of HSC and lymphoid progenitors mediated by Perk deletion, suggesting that up-regulation of endothelial Dll4 is likely responsible for Perk ablation-mediated enhanced HSC and lymphoid progenitor regeneration. Taken together, our results revealed a novel regulatory mechanism by which endothelial Dll4 expression is suppressed by PERK of UPR during transplantation while ablating Perk increases Dll4 expression. Endothelial DLL4 in the bone marrow endothelial cells is critical for supporting vascular integrity and myeloablation-induced HSC and lymphoid progenitor regeneration. Our findings suggest that targeting endothelial PERK-DLL4 axis could be a viable option to improve post-irradiation regeneration of HSC and lymphoid progenitors.

Whole-cell modeling of E. coli confirms that in vitro tRNA aminoacylation measurements are insufficient to support cell growth and predicts a positive feedback mechanism regulating arginine biosynthesis.

In Escherichia coli, inconsistencies between in vitro tRNA aminoacylation measurements and in vivo protein synthesis demands were postulated almost 40years ago, but have proven difficult to confirm. Whole-cell modeling can test whether a cell behaves in a physiologically correct manner when parameterized with in vitro measurements by providing a holistic representation of cellular processes in vivo. Here, a mechanistic model of tRNA aminoacylation, codon-based polypeptide elongation, and N-terminal methionine cleavage was incorporated into a developing whole-cell model of E. coli. Subsequent analysis confirmed the insufficiency of aminoacyl-tRNA synthetase kinetic measurements for cellular proteome maintenance, and estimated aminoacyl-tRNA synthetase kcats that were on average 7.6-fold higher. Simulating cell growth with perturbed kcats demonstrated the global impact of these in vitro measurements on cellular phenotypes. For example, an insufficient kcat for HisRS caused protein synthesis to be less robust to the natural variability in aminoacyl-tRNA synthetase expression in single cells. More surprisingly, insufficient ArgRS activity led to catastrophic impacts on arginine biosynthesis due to underexpressed N-acetylglutamate synthase, where translation depends on repeated CGG codons. Overall, the expanded E. coli model deepens understanding of how translation operates in an in vivo context.

Thermal sensitivities of respiration and protein synthesis differ among larval families of the Pacific oyster, Crassostrea gigas.

Understanding the mechanisms of biological responses to environmental change is a central theme in comparative and evolutionary physiology. Here, we analyzed variation in physiological responses to temperature, using 21 full-sibling larval families of the Pacific oyster, Crassostrea gigas. Pedigrees were confirmed with genetic markers for adult broodstock obtained from our breeding program. From these 21 larval families, 41 determinations of thermal sensitivity (Q10 values) were assayed for larvae of different sizes. For respiration, thermal sensitivity was consistent within a larval family during growth, but showed significant differences among families. Different Q10 values were evident among 21 larval families, with family accounting for 87% of variation. Specifically, four larval families maintained an increased thermal sensitivity for respiration (Q10 of 3). This physiology would confer resilience to rising temperature by matching the increased energy demand of protein synthesis (Q10 of 3 previously reported). For protein synthesis, differences in Q10 values were also observed. Notably, a family was identified that had a decreased thermal sensitivity for protein synthesis (Q10 of 1.7 cf. Q10 of 3 for other families), conferring an optimal energy allocation with rising temperature. Different thermal sensitivities across families for respiration (energy supply) and protein synthesis (energy demand) were integrated into models of energy allocation at the whole-organism level. The outcome of these analyses provides insights into the physiological bases of optimal energy allocation with rising temperature. These transgenerational (egg-to-egg) experiments highlight approaches to dissect components of phenotypic variance to address long-standing questions of genetic adaptation and physiological resilience to environmental change.

Transcription factor Creb3l1 maintains proteostasis in neuroendocrine cells

ObjectivesDynamic changes to neuropeptide hormone synthesis and secretion by hypothalamic neuroendocrine cells is essential to ensure metabolic homeostasis. The specialised molecular mechanisms that allow neuroendocrine cells to synthesise and secrete vast quantities of neuropeptides remain ill defined. The objective of this study was to identify novel genes and pathways controlled by transcription factor and endoplasmic reticulum stress sensor Creb3l1 which is robustly activated in hypothalamic magnocellular neurones in response to increased demand for protein synthesis. MethodsWe adopted a multiomic strategy to investigate specific roles of Creb3l1 in rat magnocellular neurones. We first performed chromatin immunoprecipitation followed by genome sequencing (ChIP-seq) to identify Creb3l1 genomic targets and then integrated this data with RNA sequencing data from physiologically stimulated and Creb3l1 knockdown magnocellular neurones. ResultsThe data converged on Creb3l1 targets that code for ribosomal proteins and endoplasmic reticulum proteins crucial for the maintenance of cellular proteostasis. We validated genes that compose the PERK arm of the unfolded protein response pathway including Eif2ak3, Eif2s1, Atf4 and Ddit3 as direct Creb3l1 targets. Importantly, knockdown of Creb3l1 in the hypothalamus led to a dramatic depletion in neuropeptide synthesis and secretion. The physiological outcomes from studies of paraventricular and supraoptic nuclei Creb3l1 knockdown animals were changes to food and water consumption. ConclusionCollectively, our data identify Creb3l1 as a comprehensive controller of the PERK signalling pathway in magnocellular neurones in response to physiological stimulation. The broad regulation of neuropeptide synthesis and secretion by Creb3l1 presents a new therapeutic strategy for metabolic diseases.

Emerging roles of endoplasmic reticulum proteostasis in brain development.

The development of the central nervous system requires a series of morphogenetic events that shape brain and spinal cord structures. Several brain regions and neural circuits are formed by differential gene expression patterns and cell migration events involving neurons. During neurogenesis and neuritogenesis, increased demand for protein synthesis occurs to express key neuronal proteins to generate axons, dendrites, and synapsis. The endoplasmic reticulum (ER) is a central hub controlling protein homeostasis (proteostasis), impacting a wide range of cellular processes required for brain function. Although most of the field has focused on studying the role of ER stress in neurodegenerative diseases marked by abnormal protein aggregation, accumulating evidence indicates that ER proteostasis contributes to brain development and may impact neurodevelopmental processes such as neuronal migration, differentiation, and function. Here, we review emerging evidence linking neurodevelopment with ER proteostasis and its relevance to human disorders.

Effect of trace metal contamination in sediments on the bioaccumulation of bivalve Meretrix meretrix

A quinquennial seasonal study (2015–2019) has been conducted to evaluate the bioaccumulation pattern of trace metals in Meretrix meretrix. The concentration of trace metals in the clam was observed as Cr > Cu > Ni > Zn > Pb > Cd > Hg, (Body> Mantle > Gills), similar to sediments. Contamination Factor of Cu and Cr in sediments showed strong association with the corresponding metal concentration in the body (r = 0.687, r = 0.962), mantle (r = 0.880, r = 0.956) and gills (r = 0.937, r = 0.863). Bioconcentration Factor was high for Cr followed by Ni. Mean Metal Concentration Rate (MMCR) of Cr was high and Hg was low (Body>Mantle>Gills). Our study establishes that the trace metal intake by Meretrix meretrix is associated with seasonal variation, physicochemical factors, sediment texture, chemical speciation and the metabolic stress created within the species induced from increased demand for protein synthesis. The latter resulted in the augmented rate of accumulation of Cu and Cr.

Regulation of Nucleolar Activity by MYC.

The nucleolus harbors the machinery necessary to produce new ribosomes which are critical for protein synthesis. Nucleolar size, shape, and density are highly dynamic and can be adjusted to accommodate ribosome biogenesis according to the needs for protein synthesis. In cancer, cells undergo continuous proliferation; therefore, nucleolar activity is elevated due to their high demand for protein synthesis. The transcription factor and universal oncogene MYC promotes nucleolar activity by enhancing the transcription of ribosomal DNA (rDNA) and ribosomal proteins. This review summarizes the importance of nucleolar activity in mammalian cells, MYC’s role in nucleolar regulation in cancer, and discusses how a better understanding (and the potential inhibition) of aberrant nucleolar activity in cancer cells could lead to novel therapeutics.

Enzymology and Regulation of δ1-Pyrroline-5-Carboxylate Synthetase 2 From Rice.

Under several stress conditions, such as excess salt and drought, many plants accumulate proline inside the cell, which is believed to help counteracting the adverse effects of low water potential. This increase mainly relies upon transcriptional induction of δ1-pyrroline-5-carboxylate synthetase (P5CS), the enzyme that catalyzes the first two steps in proline biosynthesis from glutamate. P5CS mediates both the phosphorylation of glutamate and the reduction of γ-glutamylphosphate to glutamate-5-semialdehyde, which spontaneously cyclizes to δ1-pyrroline-5-carboxylate (P5C). In most higher plants, two isoforms of P5CS have been found, one constitutively expressed to satisfy proline demand for protein synthesis, the other stress-induced. Despite the number of papers to investigate the regulation of P5CS at the transcriptional level, to date, the properties of the enzyme have been only poorly studied. As a consequence, the descriptions of post-translational regulatory mechanisms have largely been limited to feedback-inhibition by proline. Here, we report cloning and heterologous expression of P5CS2 from Oryza sativa. The protein has been fully characterized from a functional point of view, using an assay method that allows following the physiological reaction of the enzyme. Kinetic analyses show that the activity is subjected to a wide array of regulatory mechanisms, ranging from product inhibition to feedback inhibition by proline and other amino acids. These findings confirm long-hypothesized influences of both, the redox status of the cell and nitrogen availability, on proline biosynthesis.

Protein synthesis as a modifiable target for autism-related dendritic spine pathophysiologies.

Autism spectrum disorder (ASD) is increasingly recognized as a condition of altered brain connectivity. As synapses are fundamental subcellular structures for neuronal connectivity, synaptic pathophysiology has become one of central themes in autism research. Reports disagree upon whether the density of dendritic spines, namely excitatory synapses, is increased or decreased in ASD and whether the protein synthesis that is critical for dendritic spine formation and function is upregulated or downregulated. Here, we review recent evidence supporting a subgroup of ASD models with decreased dendritic spine density (hereafter ASD-DSD), including Nf1 and Vcp mutant mice. We discuss the relevance of branched-chain amino acid (BCAA) insufficiency in relation to unmet protein synthesis demand in ASD-DSD. In contrast to ASD-DSD, ASD models with hyperactive mammalian target of rapamycin (mTOR) may represent the opposite end of the disease spectrum, often characterized by increases in protein synthesis and dendritic spine density (denoted ASD-ISD). Finally, we propose personalized dietary leucine as a strategy tailored to balancing protein synthesis demand, thereby ameliorating dendritic spine pathophysiologies and autism-related phenotypes in susceptible patients, especially those with ASD-DSD.

The Hydroxyquinoline Analogue YUM70 Inhibits GRP78 to Induce ER Stress-Mediated Apoptosis in Pancreatic Cancer.

GRP78 (glucose-regulated protein, 78 kDa) is a key regulator of endoplasmic reticulum (ER) stress signaling. Cancer cells are highly proliferative and have high demand for protein synthesis and folding, which results in significant stress on the ER. To respond to ER stress and maintain cellular homeostasis, cells activate the unfolded protein response (UPR) that promotes either survival or apoptotic death. Cancer cells utilize the UPR to promote survival and growth. In this study, we describe the discovery of a series of novel hydroxyquinoline GRP78 inhibitors. A representative analogue, YUM70, inhibited pancreatic cancer cell growth in vitro and showed in vivo efficacy in a pancreatic cancer xenograft model with no toxicity to normal tissues. YUM70 directly bound GRP78 and inactivated its function, resulting in ER stress-mediated apoptosis. A YUM70 analogue conjugated with BODIPY showed colocalization of the compound with GRP78 in the ER. Moreover, a YUM70-PROTAC (proteolysis targeting chimera) was synthesized to force degradation of GRP78 in pancreatic cancer cells. YUM70 showed a strong synergistic cytotoxicity with topotecan and vorinostat. Together, our study demonstrates that YUM70 is a novel inducer of ER stress, with preclinical efficacy as a monotherapy or in combination with topoisomerase and HDAC inhibitors in pancreatic cancer. SIGNIFICANCE: This study identifies a novel ER stress inducer that binds GRP78 and inhibits pancreatic cancer cell growth in vitro and in vivo, demonstrating its potential as a therapeutic agent for pancreatic cancer.

Interplay between Endoplasmic Reticulum Stress and Large Extracellular Vesicles (Microparticles) in Endothelial Cell Dysfunction.

Upon increased demand for protein synthesis, accumulation of misfolded and/or unfolded proteins within the endoplasmic reticulum (ER), a pro-survival response is activated termed unfolded protein response (UPR), aiming at restoring the proper function of the ER. Prolonged activation of the UPR leads, however, to ER stress, a cellular state that contributes to the pathogenesis of various chronic diseases including obesity and diabetes. ER stress response by itself can result in endothelial dysfunction, a hallmark of cardiovascular disease, through various cellular mechanisms including apoptosis, insulin resistance, inflammation and oxidative stress. Extracellular vesicles (EVs), particularly large EVs (lEVs) commonly referred to as microparticles (MPs), are membrane vesicles. They are considered as a fingerprint of their originating cells, carrying a variety of molecular components of their parent cells. lEVs are emerging as major contributors to endothelial cell dysfunction in various metabolic disease conditions. However, the mechanisms underpinning the role of lEVs in endothelial dysfunction are not fully elucidated. Recently, ER stress emerged as a bridging molecular link between lEVs and endothelial cell dysfunction. Therefore, in the current review, we summarized the roles of lEVs and ER stress in endothelial dysfunction and discussed the molecular crosstalk and relationship between ER stress and lEVs in endothelial dysfunction.

Together we are on together we are off -a conserved rule for ribosomal RNA (rRNA) gene regulation?

Eukaryotic cells carry several hundreds of ribosomal RNA (rRNA) genes which are clustered as tandem repeats at chromosomal loci called nucleolus organizer regions (NORs). The number of rRNA genes (dosage) that are transcriptionally active at any stage of development depends on the levels of cellular demands for protein synthesis. Although it was known for quite some time that, across eukaryotes, about 50% of rRNA genes are transcriptionally silenced during the development, how the choice is made to selectively silence a subset of rRNA genes was not understood. In this review, we summarize our recent findings from model plant Arabidopsis, which led to a new hypothesis that, rRNA genes are regulated as a cluster at the level of NORs, not at the level of individual genes. And, the chromosomal location, not the sequence, dictates the activity status of rRNA genes. We also briefly summarize findings from other eukaryotic model systems which appear to support the new hypothesis on rRNA dosage control.

UAE1 inhibition mediates the unfolded protein response, DNA damage and caspase-dependent cell death in pancreatic cancer.

The Unfolded Protein Response (UPR) plays a key role in the adaptive response to loss of protein homeostasis within the endoplasmic reticulum (ER). The UPR has an adaptive function in protein homeostasis, however, sustained activation of the UPR due to hypoxia, nutrient deprivation, and increased demand for protein synthesis, alters the UPR program such that additional perturbation of ER homeostasis activates a pro-apoptotic program. Since ubiquitination followed by proteasomal degradation of misfolded proteins within the ER is a central mechanism for restoration of ER homeostasis, inhibitors of this pathway have proven to be valuable anti-cancer therapeutics. Ubiquitin activating enzyme 1(UAE1), activates ubiquitin for transfer to target proteins for proteasomal degradation in conjunction with E2 and E3 enzymes. Inhibition of UAE1 activity in response to TAK-243, leads to an accumulation of misfolded proteins within the ER, thereby aggravating ER stress, leading to DNA damage and arrest of cells in the G2/M phase of the cell cycle. Persistent drug treatment mediates a robust induction of apoptosis following a transient cell cycle arrest. These biological effects of TAK-243 were recapitulated in mouse models of PDAC demonstrating antitumor activity at a dose and schedule that did not exhibit obvious normal tissue toxicity. In vitro as well as studies in mouse models failed to show enhanced efficacy when TAK-243 was combined with ionizing radiation or gemcitabine, providing an impetus for future studies to identify agents that synergize with this class of agents for improved tumor control in PDAC.SignificanceThe UAE1 inhibitor TAK-243, mediates activation of the unfolded protein response, accumulation of DNA breaks and apoptosis, providing a rationale for the use as a safe and efficacious anti-cancer therapeutic for PDAC.

MON-009 GLUT1-Mediated Glycolysis Facilitates GnRH-Induced Secretion of Luteinizing Hormone

Reproduction requires intensive energy expenditure, and energy availability impacts the function of the reproductive endocrine HPG-axis. Accordingly, the reproductive axis is suppressed during hypoglycemia. Circulating blood glucose can directly interact with gonadotropes within the highly vascular pituitary. Therefore, it is possible that gonadotropes may sense energy availability via the presence of glucose in the circulation and integrate this status with input from GnRH neurons to regulate hormone production. Gonadotropes dominantly express glucose transporter 1 (GLUT1) and increase glucose uptake in response to GnRH. Thus, we hypothesized that gonadotropes engage glycolysis in response to GnRH stimulation due to the high energy demand of protein synthesis required for LH production. We developed an approach to sort and successfully culture primary gonadotropes from wild type mice. Using this approach, we performed extracellular flux analysis and found that gonadotropes respond to GnRH by inducing GLUT1-mediated glycolysis that is independent of mitochondrial respiration. Knock-down of GLUT1 expression in the LβT2 gonadotrope cell line, glucose restriction, or treatment with the competitive inhibitor of glycolysis, 2-DG, diminished GnRH-induced LH secretion, indicating GLUT1 expression is necessary for maximal GnRH-induced LH secretion. We confirmed this observation in primary female mouse gonadotropes by limiting glucose availability which resulted in diminished basal LH and FSH secretion. Lastly, GLUT1 expression in the pituitary correlates with GnRH receptor expression and is increased during the LH surge in a mouse model. These results implicate glucose uptake through GLUT1 as permissive for gonadotrope secretion of LH and therefore reproductive function, especially the LH surge. We conclude that GLUT1-mediated glucose uptake is an important rate-limiting step in gonadotropin synthesis and operation of the HPG-axis.

Novel functions of cytoplasmic aminoacyl-tRNA synthetases shaping the hallmarks of cancer.

With the intense protein synthesis demands of cancer, the classical enzymatic role of aminoacyl-tRNA synthetases (aaRSs) is required to sustain tumor growth. However, many if not all aaRSs also possess regulatory functions outside of the domain of catalytic tRNA aminoacylation, which can further contribute to or even antagonize cancers in non-translational ways. These regulatory functions of aaRS are likely to be manipulated in cancer to ensure uncontrolled growth and survival. This review will largely focus on the unique capacities of individual and sometimes collaborating synthetases to influence the hallmarks of cancer, which represent the principles and characteristics of tumorigenesis. An interesting feature of cytoplasmic aaRSs in higher eukaryotes is the formation of a large multi-synthetase complex (MSC) with nine aaRSs held together by three non-enzymatic scaffolding proteins (AIMPs). The MSC-associated aaRSs, when released from the complex in response to certain stimulations, often participate in pathways that promote tumorigenesis. In contrast, the freestanding aaRSs are associated with activities in both directions-some promoting while others inhibiting cancer. The AIMPs have emerged as potent tumor suppressors through their own distinct mechanisms. We propose that the tumor-suppressive roles of AIMPs may also be a consequence of keeping the cancer-promoting aaRSs within the MSC. The rich connections between cancer and the synthetases have inspired the development of innovative cancer treatments that target or take advantage of these novel functions of aaRSs.

L-type amino-acid transporter 1 (LAT1) expression is predictive of response to autologous stem cell transplantation for multiple myeloma

L-type amino acid transporter 1 (LAT1) plays a key role in cell growth and survival. Overexpression is a common feature of many malignancies to support increased protein synthesis demand. Among patients with multiple myeloma, high LAT1 expression has been shown to be associated higher risk disease but also a higher response rate following treatment with oral melphalan in clinical and pre-clinical models (Isoda, et al, Cancer Sci, 2014; Hathi, et al, J Nucl Med, 2018). Oral melphalan is infrequently used in today's clinical practice; however, high-dose intravenous melphalan is the standard of care for conditioning prior to autologous stem cell transplantation (ASCT).

Amino Acid Biosynthesis Regulation during Endoplasmic Reticulum Stress Is Coupled to Protein Expression Demands.

SummaryThe endoplasmic reticulum (ER) stress response, also known as the unfolded protein response (UPR), is a complex cellular response to ER protein misfolding that involves transcriptional regulatory branches and a PERK-mediated translational regulatory branch.Here we revealed that amino acid biosynthesis regulation is coupled to protein synthesis demands during ER stress. Specifically, we demonstrated that the UPR leads to PERK-dependent induction in the biosynthesis of specific amino acids, and to upregulation of their corresponding tRNA synthetases. Furthermore, we found that sequences of UPR-upregulated proteins are significantly enriched with these UPR-induced amino acids. Interestingly, whereas the UPR leads to repression of ER target proteins, we showed that secreted proteins tended to escape this repression and were highly enriched for the UPR-induced amino acids.Our results unravel coordination between amino acid supply, namely, biosynthesis and tRNA loading, and demand from UPR-induced proteins under ER stress, thus revealing an additional regulatory layer of protein synthesis.