• OPEN ACCESS

TDF Promotes Glycolysis and Mitochondrial Dysfunction to Accelerate Lactate Accumulation by Downregulating PGC1α in Mice

  • Yuxuan Luo1,2,#,
  • Zhiwei Chen1,#,
  • Zhao Li1,
  • Aoran Luo1,
  • Yi Zeng1,
  • Min Chen1,
  • Mingli Peng1,
  • Hong Ren1,*  and
  • Peng Hu1,* 
 Author information
Journal of Clinical and Translational Hepatology 2023;11(4):998-1002

DOI: 10.14218/JCTH.2022.00082

Abstract

Keywords

Tenofovir disoproxil fumarate (TDF), is a product of tenofovir and has been recommended for long-term use by guidelines1 because of its favorable efficacy in the treatment of human immunodeficiency virus (HIV) and hepatitis B virus (HBV) infection. Hence, a better understanding of the safety profiles of long-term TDF use is extremely important. Lactic acidosis, as a rare but fatal adverse event of TDF, were reported both in HIV-infected patients,2–4 and in CHB patients.5–7 Hyperlactatemia occurred in 15.6% HIV-infected patients using TDF in a Cameroon cohort study8 and was 3% in another South Africa cohort study.9 Therefore, TDF increases the risk of abnormal serum lactate, but the mechanism is unclear.

In this study, we treated mice with TDF by oral gavage for 4 months to simulate long-term use in humans. Detailed methods are described in the Supplementary File 1. As shown in Supplementary Figure 1A, TDF treatment significantly increased the blood lactate levels in mice. The body weight and liver weight were similar between TDF-treated mice and control mice (Supplementary Fig. 1B–D).

To explore the underling mechanism by which TDF increased lactate levels, we first analyzed lactate generation in skeletal muscle, as lactate is the end-product of glycolysis and is primarily produced in muscle. TDF treatment resulted in a large increase of pyruvate levels in skeletal muscle (Fig. 1A). The activity of lactate dehydrogenase-A (LDHA) was also elevated in response to TDF (Fig. 1B). Additionally, there was no difference in pyruvate dehydrogenase (PDH) activity between the control and TDF-treated mice (Fig. 1C), but the activity of phosphofructokinase (PFK), a key enzyme in glycolysis, was enhanced in the skeletal muscle of TDF-treated mice (Fig. 1D). The mRNA expression of enzymes involved in glycolysis was unchanged by TDF, except for hexokinase 2 (HK2) (Fig. 1E). We also evaluated the effect of TDF on glucose uptake by measuring the expression of glucose transporter type 4 (GLUT4). As shown in Figure 1E, the GLUT4 mRNA levels were decreased in TDF-treated mice. It is worth noting that the glycogen content in skeletal muscle was much lower in TDF-treated mice than that in the controls (Fig. 1F). The data indicate that TDF accelerated glycolysis in skeletal muscle.

TDF accelerates glycolysis in skeletal muscle.
Fig. 1  TDF accelerates glycolysis in skeletal muscle.

(A) Pyruvate levels in the skeletal muscle of the control and TDF-treated mice. (B-D) Activity of LDHA (B), PDH (C) and PFK (D) in the skeletal muscle of control mice and TDF-treated mice. (E) mRNA levels of genes related to glycolysis in TDF-treated skeletal muscle. (F) Representative images (left) and quantification (right) of PAS staining in skeletal muscle sections from the control and TDF-treated mice. Scale bar, 100µm. n=4–9. *p<0.05, **p<0.01, ***p<0.001. LDHA, lactate dehydrogenase-A; PDH, pyruvate dehydrogenase; PFK, phosphofructokinase; GLUT4, glucose transporter type 4; HK2, hexokinase 2; PGI, phosphoglucose isomerase; PFK, phosphofructokinase; ALDOA, fructose diphosphate aldease A; ENO3, enolase 3; PK, pyruvate kinase; GAPDH, glyceraldehyde-phosphate dehydrogenase; PAS, periodic acid-Schiff.

To assess whether the impact of TDF on lactate production was specific to skeletal muscle, we next examined glycolysis in the myocardium. Pyruvate levels were similar in the hearts of control mice and TDF-treated mice (Supplementary Fig. 2A). TDF also failed to affect LDHA, PDH and PFK activity in heart tissue (Supplementary Fig. 2B–D). Additionally, the expression of glycolysis-related enzymes and the glycogen content was unchanged in the hearts of TDF-treated mice (Supplementary Fig. 2F). These data suggest that TDF does not affect glycolysis in the heart.

After we confirmed that TDF increased lactate production specifically in skeletal muscle, we next investigated whether TDF affected lactate clearance. Lactate is primarily cleared by gluconeogenesis in the liver and kidney,10,11 thus, we examined the expression of phosphoenolpyruvate carboxykinase (Pepck) and glucose 6-phosphatase (G6pase), two key enzymes in gluconeogenesis. We found that TDF did not influence the expression and distribution of either Pepck or G6pase in the liver and kidney (Supplementary Fig. 3A–D). Additionally, the glycogen content in the liver and kidney did no differ between the control and TDF-treated mice (Supplementary Fig. 3E). Moreover, the blood glucose levels remained unchanged in TDF-treated mice (Supplementary Fig. 3F). Collectively, the data suggest that TDF had no effect on gluconeogenesis in the liver and kidney.

It is well known that mitochondria play crucial roles in the regulation of lactate metabolism. Previous studies have demonstrated that mitochondrial dysfunction without abnormal glycolysis results in high lactate levels.12 Meanwhile, NAs were reported to be associated with mitochondrial toxicity.13 As such, we evaluated whether TDF influenced mitochondrial function in muscle, liver, and kidney. As shown in Figure 2A, TDF treatment produced no significant changes in the activity of mitochondrial complex II in the skeletal muscle, heart, liver, and kidney (Fig. 2A). The activity of complex III and IV was markedly inhibited in the skeletal muscle of TDF-treated mice, but was maintained in the heart, liver, and kidney (Fig. 2A). A similar trend was observed in ATP production (Fig. 2B). We next measured the mitochondrial DNA (mtDNA) copy number in the mice. As shown in Figure 2C, TDF reduced the mtDNA copy number in skeletal muscle, but not in other tissues (Fig. 2C). Alterations of the mtDNA copy number are related to mtDNA transcription, so we examined the expression of mitochondrial transcription factors. We found that TDF did not influence the expression of mitochondrial transcription factor A (TFAM) and mitochondrial transcription factor B2 (TFB2M), but did result in a decrease expression of mitochondrial transcription factor B1 (TFB1M) in skeletal muscle (Fig. 2D, E and Supplementary Fig. 4A, B). However, the changes were not observed in the heart, liver, and kidney (Fig. 2D and Supplementary Fig. 4A, B). Together, the data indicate that TDF impaired mitochondrial function in skeletal muscle, but not in the heart, liver, and kidney.

TDF impairs mitochondrial function in skeletal muscle.
Fig. 2  TDF impairs mitochondrial function in skeletal muscle.

(A) The activity of mitochondrial complex II (left), III (middle) and IV (right) of the skeletal muscle, heart, liver and kidney from the control and TDF-treated mice. (B) ATP production of TDF-treated skeletal muscle, heart, liver, and kidney. (C) Mitochondrial DNA copy number in TDF-treated skeletal muscle, heart, liver, and kidney. (D) TFB1M mRNA levels in the indicated tissues. (E) Protein levels (left) and quantification (right) of TFB1M in the skeletal muscle of the control and TDF-treated mice. n=4–8. *p<0.05, **p<0.01, ***p<0.001. TFB1M, mitochondrial transcription factor B1; SK, skeletal muscle; ATP, adenosine triphosphate; mtDNA, mitochondrial DNA.

To investigate the underlying mechanism by which TDF affects glycolysis and mitochondrial function in skeletal muscle, we performed RNA sequencing (RNA-seq) analysis in skeletal muscle from the control and TDF-treated mice, focusing on genes related to glucose/energy metabolism. We detected 24 upregulated and four downregulated genes in this pathway (Fig. 3A). Subsequently, we analyzed the expression of these genes by quantitative PCR, and we found that the mRNA levels of PGC1α, which is a critical molecule in the regulation of lactate homeostasis and mitochondrial biosynthesis,14,15 were most affected by TDF in skeletal muscle (Fig. 3B). The results of western blotting further confirmed that TDF treatment led to a marked decrease in PGC1α expression in skeletal muscle (Fig. 3C). Next, we screened the upstream molecules of PGC1α and found that cAMP response element–binding protein (CREB) was strongly downregulated by TDF (Fig. 3C, D). We did not observe any significant changes in the expression of other upstream transcription factors of PGC1α, such as myocyte enhancer factor 2 (MEF2), forkhead box O1 (FoxO1) and activating transcription factor 2 (ATF2), in TDF-treated skeletal muscle (Supplementary Fig. 5A). Additionally, the phosphorylation levels of CREB were also decreased after TDF treatment (Fig. 3C). However, the effects of TDF were not observed in the heart (Fig. 3D, E and Supplementary Fig. 5B). Collectively, the data suggest that TDF downregulated PGC1α expression in skeletal muscle.

TDF down-regulates the expression of PGC1α in skeletal muscle.
Fig. 3  TDF down-regulates the expression of PGC1α in skeletal muscle.

(A) Heat map of differentially expressed genes related to the glucose and energy metabolism pathway in the skeletal muscle of the control and TDF-treated mice. Bright green, upregulation; black, no change; bright red, downregulation. (B) Gene expression in the skeletal muscle of control mice and TDF-treated mice was analyzed by quantitative PCR. (C) Representative western blotting showing the levels of PGC1α, p-CREB and CREB in the skeletal muscle of the control and TDF-treated mice. Quantification data is shown in the right panel. (D) CREB mRNA levels in the skeletal muscle and hearts. (E) Representative western blotting for PGC1α, p-CREB and CREB in the hearts from control mice and mice following TDF administration. Quantification data is shown in the right panel. (F) Schematic diagram showing that TDF promotes glycolysis and impairs mitochondrial function by downregulating PGC1α in skeletal muscle, and thus leading to an increase in serum lactate levels. n=4–8. *p<0.05, **p<0.01, ***p<0.001. TCA cycle, tricarboxylic acid cycle.

In conclusion, TDF elevated lactate levels by accelerating glycolysis and disturbing mitochondrial function in skeletal muscle, which was caused, at least in part, by TDF-mediated downregulation of PGC1α (Fig. 3F). Therefore, we should pay attention to blood lactate levels in patients during clinical use of TDF.

Supporting information

Supplementary File 1

Supplementary methods.

(DOCX)

Supplementary Fig. 1

TDF induces elevated serum lactate levels in mice.

(A) Blood lactate concentration of control mice and mice treated with TDF for 4 months. (B–D), Body weight (B), liver weight (C) and LW/BW (D) in control and TDF-treated mice. n=6–9. **p<0.01. LW, liver weight; BW, body weight.

(TIF)

Supplementary Fig. 2

TDF has no effect on glycolysis in the heart.

(A) Pyruvate levels in the hearts of the control mice and mice treated with TDF. (B-D) The activity of LDHA (B), PDH (C) and PFK (D) in the hearts of mice following TDF administration. (E) mRNA levels of glycolytic genes in the hearts of the control and TDF-treated mice. (F) Representative images (left) and quantification (right) of PAS staining in cardiac sections from the control mice and TDF-treated mice. Scale bar, 100 µm. n=3–9. LDHA, lactate dehydrogenase-A; PDH, pyruvate dehydrogenase; PFK, phosphofructokinase; GLUT4, glucose transporter type 4; HK2, hexokinase 2; PGI, phosphoglucose isomerase; PFK, phosphofructokinase; ALDOA, fructose diphosphate aldease A; ENO3, enolase 3; PK, pyruvate kinase; GAPDH, glyceraldehyde-phosphate dehydrogenase; PAS, periodic acid-Schiff.

(TIF)

Supplementary Fig. 3

TDF does not influence gluconeogenesis in the liver and kidney.

(A) Western blotting showing the protein levels of Pepck and G6pase in the liver of the control mice and TDF-treated mice. Quantification data is shown in the right panel. (B) Expression (left) and quantification (right) of Pepck and G6pase in the kidneys of the control and TDF-treated mice. (C and D) Representative immunohistochemical staining showing the expression of Pepck (C) and G6pase (D) in the liver and kidney from the control mice and TDF-treated mice. Quantification data is shown in the right panel. (E) Representative images (left) and quantification (right) of PAS staining in the liver and kidney of the TDF-treated mice and the control mice. (F) Blood glucose levels in mice. n=4–6. Pepck, phosphoenolpyruvate carboxykinase; G6pase, glucose-6 phosphatase.

(TIF)

Supplementary Fig. 4

mRNA levels of TFAM (A) and TFB2M (B) in skeletal muscle, heart, liver and kidney of control mice and mice following TDF treatment.

n = 6–8. TFAM, mitochondrial transcription factor A; TFB2M, mitochondrial transcription factor B2; SK, skeletal muscle.

(TIF)

Supplementary Fig. 5

mRNA levels of PGC1α upstream molecules in skeletal muscle and PGC1α expression in the heart.

(A) mRNA levels of PGC1α upstream molecules in skeletal muscle from control mice and TDF-treated mice. (B) mRNA levels of PGC1α in the hearts of control and TDF-treated mice. n=5–8. PGC1α, peroxisome proliferator-activated receptor-γ coactivator 1α; MEF2, myocyte enhancer factor 2A; ATF2, activating transcription factor 2; FoxO1, forkhead box O1.

(TIF)

Abbreviations

ATF2: 

activating transcription factor 2

CREB: 

cAMP response element–binding protein

FoxO1: 

forkhead box O1

G6pase: 

glucose 6-phosphatase

GLUT4: 

glucose transporter type 4

HBV: 

hepatitis B virus

HIV: 

human immunodeficiency virus

HK2: 

hexokinase 2

LDHA: 

lactate dehydrogenase-A

MEF2: 

myocyte enhancer factor 2

PAS: 

periodic acid-Schiff

PDH: 

pyruvate dehydrogenase

Pepck: 

phosphoenolpyruvate carboxykinase

PFK: 

phosphofructokinase

PGC1α: 

peroxisome proliferator-activated receptor-γ coactivator 1α

RNA-seq: 

RNA sequencing

TDF: 

Tenofovir disoproxil fumarate

TFAM: 

mitochondrial transcription factor A

TFB1M: 

mitochondrial transcription factor B1

TFB2M: 

mitochondrial transcription factor B2

Declarations

Acknowledgement

We thank Guangshengtang Pharmaceutical Co., Ltd (Fujian, China) for kindly gifting the TDF to us.

Ethical statement

The animal studies were approved by the Animal Ethics Committee of Second Affiliated Hospital of Chongqing Medical University.

Data sharing statement

The datasets used and analyzed during the current study are available from the corresponding author upon reasonable request.

Funding

This work was supported in part by grants from the National Science and Technology Major Project of China (2017ZX10202203008, 2017ZX10202203007), the National Natural Science Foundation of China (81772171), the Chongqing Talents Project (cstc2021ycjh-bgzxm0150), and Remarkable Innovation–Clinical Research Project, the Second Affiliated Hospital of Chongqing Medical University.

Conflict of interest

HR has been an editor-in-chief of Journal of Clinical and Translational Hepatology since 2013. PH has been an associate editor of Journal of Clinical and Translational Hepatology since 2022. The other authors have no conflict of interests related to this publication.

Authors’ contributions

Study concept and design (PH, HR), acquisition of data (YL, ZC, ZL, AL), analysis and interpretation of data (YL, ZC, ZL, YZ), drafting of the manuscript (YL, ZC, ZL), critical revision of the manuscript for important intellectual content (YL, ZC, MP, MC, PH, HR). All authors have made a significant contribution to this study and have approved the final manuscript.

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