Integrative transcriptomics-metabolomics approach to identify metabolic pathways regulated by glutamine synthetase activity

doi:10.3724/SP.J.1123.2024.04003

Abstract

Abstract:

Glutamine synthetase (GS), the only enzyme responsible for de novo glutamine synthesis, plays a significant role in cancer progression. As an example of the consequences of GS mutations, the R324C variant causes congenital glutamine deficiency, which results in brain abnormalities and neonatal death. However, the influence of GS-deficient mutations on cancer cells remains relatively unexplored. In this study, we investigated the effects of GS and GS-deficient mutations, including R324C and previously unreported K241R, which serve as models for GS inactivation. This study provided intriguing insights into the intricate relationship between GS mutations and cancer cell metabolism.

Our findings strongly support recent studies that suggest GS deletion leads to the suppression of diverse signaling cascades associated with glutamine metabolism under glutamine-stripping conditions. The affected processes include DNA synthesis, the citric acid cycle, and reactive oxygen species (ROS) detoxification. This suppression originates from the inherent inability of cells to autonomously synthesize glutamine under glutamine-depleted conditions. As a key source of reduced nitrogen, glutamine is crucial for the formation of purine and pyrimidine bases, which are essential building blocks for DNA synthesis. Furthermore, the citric acid cycle is inhibited by the absence of negatively charged glutamate within the mitochondrial matrix, particularly when glutamine is scarce. This deficiency decreases the flux of α-ketoglutarate (α-KG), a principal driver of the citric acid cycle. Intermediate metabolites of the citric acid cycle directly or indirectly contribute to the generation of nicotinamide adenine dinucleotide phosphate (NADPH) oxidase, a core component of redox homeostasis.

Using the GS_R324C and GS_K241R mutants, we conducted an integrative transcriptomics and metabolomics analysis. The GS mutants with reduced activity activated multiple amino acid biosynthesis pathways, including arginine-proline, glycine-serine-threonine, and alanine-aspartate-glutamate metabolism. This intriguing behavior led us to hypothesize that despite hindrance of the citric acid cycle, abundant intracellular glutamate is redirected through alternative processes, including transamination. Simultaneously, key metabolic enzymes in the amino acid synthesis pathways, such as glutamic-oxaloacetic transaminase 1 (GOT1), glutamic-pyruvic transaminase 2 (GPT2), pyrroline-5-carboxylate reductase 1 (PYCR1), and phosphoserine aminotransferase 1 (PSAT1), exhibited increased mRNA levels. Additionally, GS deficiency appeared to upregulate the expression of glutamine transporters SLC38A2 and SLC1A5. Thus, restricting extracellular amino acids, such as glutamine, induces a stress response while promoting transcription or translation by a select group of genes, thereby facilitating cellular adaptation. However, similar to GS_WT, both GS_R324C and GS_K241R were modulated by glutamine treatment.

Among GS-activity-dependent behaviors, the increased expression of numerous aminoacyl-tRNA synthetases (ARSs), which are critical for aminoacyl-tRNA biosynthesis, remains poorly understood. Most ARS-encoding genes are transcriptionally induced by activating transcription factor 4 (ATF4), the expression of which increases under oxidative stress, endoplasmic reticulum stress, hypoxia, and amino acid limitation. In GS-deficient cells, the increased expression of ATF4 was accompanied by pronounced stress caused by glutamine starvation. Thus, ARS upregulation may predominantly arise from increased ATF4 expression in GS-deficient cells. Additionally, transcriptomic analysis revealed the differential expression of specific genes, regardless of GS activity, suggesting that GS is involved in various processes other than glutamine synthesis, including angiogenesis. Although our omics study was limited to H1299 cells, in subsequent experiments, we validated our findings using additional cell lines, including Hepa1-6 and LN-229. To attain a more comprehensive understanding of the impact of the newly identified GS_K241R mutant, our investigation should be extended to various cell types and mouse models.

In summary, we identified and investigated GS-deficient mutations in cancer cells and conducted an integrative transcriptomics-metabolomics analysis with comparisons to wild-type GS. This comprehensive approach provided crucial insights into the intricate pathways modulated by GS activity. Our findings advance the understanding of how GS functions in the context of reprogrammed cellular metabolism, particularly during glutamine deprivation. The altered metabolism triggered by elevated glutamate levels arising from GS mutations highlights the remarkable plasticity of cancer cell metabolism. Notably, considering the increasing research focus on GS as a potential therapeutic target in various cancer types, the findings of this study could provide innovative perspectives for drug development and the formulation of clinical treatment strategies.

Key words: glutamine synthetase mutation, transcriptomics, metabolomics, lung cancer, glutamine

CLC Number:

O658

LING Ting, SHI Jing, FENG Tingze, PEI Shaojun, LI Siyi, PIAO Hailong. Integrative transcriptomics-metabolomics approach to identify metabolic pathways regulated by glutamine synthetase activity[J]. Chinese Journal of Chromatography, 2025, 43(3): 207-219.

Figures/Tables 6

Table 1 Primers used in quantitative real-time PCR (qPCR) assay

Gene	Forward sequence	Reverse sequence
GLUL	GCCTCAGGGTGAGAAAGTCC	TCCGTTTACAGGTGTGCCTC
GLNS2	GGCACATGCCAAGCTGGATA	AGTGGCTCTGCTAGGGAGAA
POLE2	TGTTTGTACCTGGTCCAGAGG	TCTTGGAAAAGAGCCAGGGT
FEN1	CCCAAAGGCCAGTCATCCCT	GCGGTAGAACATGCCCATCA
MCM4	TCCTTGTCGCGCAGGTACT	TCAAAGTCAAGAGGGATAGCTGA
CCNB1	GACCTGTGTCAGGCTTTCTCTG	GGTATTTTGGTCTGACTGCTTGC
CCND1	TCTACACCGACAACTCCATCCG	TCTGGCATTTTGGAGAGGAAGTG
CCND3	AGATCAAGCCGCACATGCGGAA	ACGCAAGACAGGTAGCGATCCA
CDC6	GGAGATGTTCGCAAAGCACTGG	GGAATCAGAGGCTCAGAAGGTG
ATF4	TTCTCCAGCGACAAGGCTAAGG	CTCCAACATCCAATCTGTCCCG

Fig. 1 Enzyme activities of glutamine synthetase (GS) and GS_K241R a: Enzyme activities of GS (wild type (WT) and mutant K241R), as determined by the accumulation of γ-glutamyl hydroxamate (bottom), and western blot analysis of protein expression (top). b: Enzyme activities of GS_WT, GS_K241R, GS_K241A and GS_K241G, as determined by the accumulation of γ-glutamyl hydroxamate (bottom, n=3), and western bolt analysis of protein expression (top). c: Enzyme activities of GS_WT, GS_K241R, and GS_R324C, as determined by the accumulation of γ-glutamyl hydroxamate (bottom, n=3), and western blot analysis of protein expression (top). d: Glutamine-producing activities of GS_WT and GS_K241R in GS-knockout H1299 cells (m+0: unlabeled glutamine, m+1: glutamine labeled with one 15N atom, and m+2: glutamine labeled with two 15N atoms), as determined by GC-MS analysis of the 15N-labeled glutamine fractions (bottom), and western blot analysis of protein expression (top). EV: empty vector; ns: not significant.

Fig. 2 RNA sequencing analysis of GS-knockout (KO) H1299 cells a: Western blot analysis of GS-KO H1299 cells. b: Volcano plot of differential mRNA levels in control and GS-KO cells (cut-off criteria: P value<0.05, |log2 Fold change|>0.5; blue and red plots indicate downregulated and upregulated mRNA, respectively). c: Gene set enrichment analysis (GSEA) results for 402 differential mRNA levels. d: Normalized enrichment score (NES) analysis. e: mRNA levels of genes associated with the DNA synthesis pathway.

Fig. 3 RNA sequencing analysis of GS-reexpressed H1299 cells a: Western blot analysis (top) and relative mRNA levels (bottom, n=3) of GS-KO H1299 cells transfected with GS_WT, GS_K241R, and GS_R324C plasmids. b: Heatmap of gene expression changes in the cells in (a). c: Volcano plot of differential mRNA levels in GS_K241R and GS_R324C cells (cut-off line at P value=0.01; blue and red plots indicate downregulated and upregulated mRNA, respectively). d: Pathway analysis of 1371 differential mRNA levels. e: mRNA levels of genes associated with the cell cycle (n=3).

Fig. 4 Effects of GS mutations on metabolites and metabolic pathways in H1299 cells a: MetaboAnalyst analysis of metabolic pathways using 41 altered metabolites (VIP>1). b: Venn diagram of differential metabolites in GS-KO H1299 cells transfected with GS_WT, GS_K241R, and GS_R324C plasmids using one-way analysis of variance. c: Changes in guanosine diphosphate, N-acetylputrescine, glutamine, N-acetylglutamic acid, adenosine diphosphate, and creatine in EV, GS_WT, GS_K241R, and GS_R324C H1299 cells (n=5; data are expressed as mean±SD).

Fig. 5 Integration of transcriptomics and metabolomics to analyze altered metabolic pathways affected by GS-deficient mutations a: Venn diagram of altered metabolic pathways in the transcriptomics-metabolomics analysis. b: ATF4 mRNA level in GS-KO H1299 and LN-229 cells transfected with EV, GS_WT, GS_K241R, and GS_R324C plasmids. c: Diagram of integrated metabolites and genes involved in arginine-proline metabolism, glycine-serine-threonine metabolism, aminoacyl-tRNA biosynthesis, and alanine-aspartate-glutamate metabolism (red and blue indicate increased and decreased metabolites or genes, respectively, in GS_K241R and GS_R324C cells compared with GS_WT cells). d: Transwell migration assay. Representative images and data quantification for H1299 cells that migrated through the transwell with ectopic expression of EV, GS_WT, GS_K241R, or GS_R324C (data from three independent experiments). Scale bar: 100 μm.

References

[1]	Gyamfi J, Kim J, Choi J. Int J Mol Sci, 2022, 23(3): 1155
[2]	Seyfried T N, Shelton L M. Nutr Metab, 2010, 7(1): 7
[3]	Seyfried T N. Front Cell Dev Biol, 2015, 3: 43
[4]	Yang L, Moss T, Mangala L S, et al. Mol Syst Biol, 2014, 10(5): 728
[5]	Green C R, Wallace M, Divakaruni A S, et al. Nat Chem Biol, 2016, 12(1): 15
[6]	Hensley C T, Wasti A T, DeBerardinis R J. J Clin Invest, 2013, 123(9): 3678
[7]	Locasale J W. Nat Rev Cancer, 2013, 13(8): 572
[8]	Shuvalov O, Petukhov A, Daks A, et al. Oncotarget, 2017, 8(14): 23955
[9]	Zhang Y, Morar M, Ealick S E. Cell Mol Life Sci, 2008, 65(23): 3699
[10]	Lieu E L, Nguyen T, Rhyne S, et al. Exp Mol Med, 2020, 52(1): 15
[11]	Pegg A E. IUBMB Life, 2009, 61(9): 880
[12]	Pietrocola F, Galluzzi L, Bravo-San Pedro J M, et al. Cell Metab, 2015, 21(6): 805
[13]	Fan J, Ye J, Kamphorst J J, et al. Nature, 2014, 510(7504): 298
[14]	Chung W J, Lyons S A, Nelson G M, et al. J Neurosci, 2005, 25(31): 7101
[15]	Janicki R H, Goldstein L. Am J Physiol, 1969, 216(5): 1107
[16]	Wasfy R E, Shams Eldeen A A. Asian Pac J Cancer Prev, 2015, 16(11): 4769
[17]	Suárez I, Bodega G, Fernández B. Neurochem Int, 2002, 41(2/3): 123
[18]	Strohecker A M. Cancer Discov, 2013, 3(11): 1272
[19]	Annese T, Tamma R, Ruggieri S, et al. Cancers (Basel), 2019, 11(3): 381
[20]	Fan S, Wang Y, Zhang Z, et al. J Cell Biochem, 2018, 119(7): 6008
[21]	Wang L, Peng W, Wu T, et al. Cell Death Discov, 2018, 4: 24
[22]	Wang Y, Fan S, Lu J, et al. J Cell Biochem, 2017, 118(8): 2018
[23]	Tardito S, Oudin A, Ahmed S U, et al. Nat Cell Biol, 2015, 17(12): 1556
[24]	Vettore L, Westbrook R L, Tennant D A. Br J Cancer, 2020, 122(2): 150
[25]	Häberle J. NEJM, 2005, 353(18): 1926
[26]	Häberle J, Shahbeck N, Ibrahim K, et al. Molecular Genetics and Metabolism, 2011, 103(1): 89
[27]	Yan M, Liu J, Xia T, et al. Chinese Journal of Chromatography, 2019, 37(8): 887
[27]	严敏, 刘静, 夏天, 等. 色谱, 2019, 37(8): 887
[28]	Xia T, Chen D, Liu X, et al. Cell Death & Disease, 2022, 13(4): 314
[29]	Haghighat N. Neurochem Res, 2005, 30(5): 661
[30]	Zeng J, Yin P, Tan Y, et al. J Proteome Res, 2014, 13(7): 3420
[31]	Eelen G, Dubois C, Cantelmo A R, et al. Nature, 2018, 561(7721): 63
[32]	Xu X, Wang X, Chen Q, et al. J Transl Med, 2023, 21(1): 307
[33]	Piao H L, Yuan Y, Wang M, et al. Nat Cell Biol, 2014, 16(3): 245
[34]	Ling T, Li S, Chen H, et al. FASEB J, 2023, 37(12): e23319
[35]	Hu S, Deng L, Wang H, et al. Cytotechnology, 2011, 63(3): 247
[36]	MacKerell A, Frieg B, Görg B, et al. PLOS Comput Biol, 2016, 12(2): e1004693
[37]	Bolzoni M, Chiu M, Accardi F, et al. Blood, 2016, 128(5): 667
[38]	Chiu M, Taurino G, Bianchi M G, et al. Int J Mol Sci, 2018, 19(4): 1099
[39]	Shan J, Zhang F, Sharkey J, et al. Nucleic Acids Res, 2016, 44(20): 9719
[40]	Sung Y, Yoon I, Han J M, et al. Exp Mol Med, 2022, 54(5): 553
[41]	Yang L. Annu Rev Biomed Eng, 2017, 19: 163
[42]	Chen L, Cui H. Int J Mol Sci, 2015, 16(9): 22830
[43]	Stretton C, Lipina C, Hyde R, et al. Biochim Biophys Acta Mol Cell Res, 2019, 1866(6): 978
[44]	Gazzola R F, Sala R, Bussolati O, et al. FEBS Lett, 2001, 490(1/2): 11
[45]	Amaya M L, Inguva A, Pei S, et al. Blood, 2022, 139(4): 584
[46]	Singleton D C, Harris A L. Expert Opin Ther Targets, 2012, 16(12): 1189
[47]	Furusawa A, Miyamoto M, Takano M, et al. Carcinogenesis, 2018, 39(6): 758
[48]	Yang L, Achreja A, Yeung T L, et al. Cell Metab, 2016, 24(5): 685