Correspondence to editorial on “Liver sinusoidal endothelial cell: An important yet often overlooked player in the liver fibrosis”

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Clin Mol Hepatol. 2024;30(4):1002-1004
Publication date (electronic) : 2024 May 17
doi : https://doi.org/10.3350/cmh.2024.0357
School of Life Sciences, Beijing University of Chinese Medicine, Beijing, China
Corresponding author : Xiaojiaoyang Li School of Life Sciences, Beijing University of Chinese Medicine, 11 Bei San Huan Dong Lu, Beijing 100029, China Tel: +8615711163102, Fax: +86-010-53912158, E-mail: xiaojiaoyang.li@bucm.edu.cn
Editor: Han Ah Lee, Chung-Ang University College of Medicine, Korea
Received 2024 May 14; Accepted 2024 May 15.

Dear Editor,

Yasuko Iwakiri recently shared the professional views regarding our review on the role of liver sinusoidal endothelial cells (LSECs) in the process of liver fibrosis [1]. The author provided a comprehensive understanding of the structural changes of LSECs including fenestrae and capillarization, nitric oxide (NO)-dependent LSECs-hepatic stellate cells (HSCs) communication, the scavenging capacity of LSECs and the heterogeneity of LSECs.

In liver, a fusion of nutrient-rich blood from the portal vein’s terminal branches with oxygen-enriched blood from the hepatic artery occurs. Then, the mixed blood travels through an intricate network of sinusoidal vessels and subsequently enters the central venules and hepatic vein. These sinusoids are enveloped by LSECs, whose distinctive position dictates their function. Based on the phagocytic capability of Kupffer cells, most past studies held the belief that clearance within the liver was primarily orchestrated by these cells [2]. Currently, an increasing number of studies have revealed that despite LSECs normally lacking phagocytic capability, they could also transport lipoprotein via fenestrae as well as clear wastes and pathogens in blood via scavenger receptors-controlled endocytosis [3]. Given that the fenestrae of LSECs not only serve as a hallmark of healthy LSECs but also fulfill crucial functions, the number of related research is increasing but still needs further studies. For example, apart from scanning electron microscopy, there were no specific molecular markers that could represent fenestrae. Plasmalemma vesicle-associated protein (PLVAP) is a dimeric protein constituent of the diaphragm of diaphragm-fenestrae, whose deficiency results in the lack of fenestrations. During liver fibrosis, the number of fenestrations is supposed to decrease. However, the PLVAP expression of LSECs was significantly upregulated in all zones in cirrhotic livers [4], indicating that PLVAP might affect other LSEC functions except fenestrae. Therefore, it was urgently needed to find a maker of LSEC fenestrae. Furthermore, except for cytoskeleton remodeling, recent research reported that intracellular protein disulfide isomerase A1 (PDIA1) showed regulation in the dynamics of LSEC fenestrae [5]. The reduction of fenestrae due to PDIA1 inhibition did not accompany significant cytoskeletal rearrangements. This complements our research findings on the dynamic reshaping of the cytoskeleton [6].

At present, the majority of the researchers that focused on LSECs distinguished LSECs by the traditional and canonical endothelial cells (ECs) markers such as CD31, VEGFR2, LYVE1. However, none of these markers are liver-specific. On the one hand, LSECs and ECs shared the same markers such as CD31 and VEGFR2. On the other hand, the recognized LSECs marker, LYVE1, also showed abundant expression in lymphatics and lung tissues. Therefore, there was an urgent need to find LSECs markers that could distinguish LSECs from ECs and were specifically expressed in liver region. LSECs-specific Cre mouse model will help unravel the intricate biology of LSECs in both health and disease and hold immense promise for the development of targeted therapies. Interestingly, a current study has identified oncoprotein-induced transcript 3 (Oit3) as a promising hallmark gene for targeting LSECs through single-cell RNA sequencing (scRNAseq) [7]. They also established Oit3-CreERT2-tdTomato mice and found tdTomato only showed up in liver rather than other organs. Furthermore, tdTomato-labeled cells were not only distinguishable from other types of liver cells but also exhibited CD31 positivity in 98.76% of cases and colocalized with Lyve1, indicating that Oit3 was worthy for further investigations and applications.

Detecting differentially expressed genes in primary LSECs through quantitative real-time PCR or RNA-seq was a pivotal method for studying the mechanisms underlying LSEC functions and elucidating the pharmacological mechanisms of drugs targeting LSECs. However, the attainment of pure isolation of LSECs was challenging due to the possibility of contamination with other cell types, thereby potentially influencing the overall interpretation of the results. With the advancements in scRNA-seq, this problem was probably solved. As reported, human ECs were identified as CD45negCD31CD38+neg cells, with sinusoids characterized phenotypically as CD45negCD31CD38+neg CD14CD34+low, and large vessels as CD45negCD31CD38++neg CD14CD34+highCD9 [8]. Furthermore, considerable attention has been directed towards understanding the importance of LSEC heterogeneity in both healthy and injured conditions. As Yasuko Iwakiri mentioned, there were two LSECs populations identified as CD34+PLVAP+VWA1+ and CD34+PLVAP+ACKR1+ based on the scRNA-seq from normal and cirrhotic patients. Another study identified two subpopulations of LSECs, including Egr1hi LSECs and Ly6ahi LSECs, that emerged in the early stages of metabolic dysfunction-associated steatohepatitis (MASH) progression and experienced dramatic proliferation with the aggravation of MASH [9]. Notably, a cluster of C-Kit-positive LSECs was proven to restore mitophagy and alleviate MASH development. Thus, demonstrating the different functions of subpopulations of LSECs might reveal the complex roles of LSECs in liver fibrosis.

Given the fact that there are no FDA-approved anti-fibrotic drugs for liver fibrosis, this remains a field ripe with exploration potential. Blood-tonifying and blood-activating herbs that belong to traditional Chinese medicine have shown therapeutic effects on angiogenesis-related conditions such as cardiovascular diseases and ischemia-reperfusion injury in clinical practice [10,11]. Li et al. [12] extensively detailed Chinese herbs renowned for their ability to inhibit pathological angiogenesis, aiming to alleviate liver fibrosis. In our review, we also reported that Fuzhenghuayu and Xuefuzhuyu significantly inhibited the dedifferentiation of LSECs, suggesting further investigation into Chinese herbs and related components regulating LSECs and their regulatory mechanisms.

Overall, we found these professional comments quite inspiring for future research. Studies aimed at unraveling the intricate biology of LSECs in both health and disease hold immense promise for the development of targeted therapies. A comprehensive understanding of LSEC heterogeneity, molecular signaling pathways, and their dynamic interplay within the liver microenvironment will undoubtedly pave the way for more effective treatments for liver fibrosis and its associated complications.

Notes

Authors’ contribution

Xiaojiaoyang Li: Resources, Supervision, Writing-Review & Editing. Jiaorong Qu: Investigation, Writing-Original Draft. Le Wang: Writing-Original Draft.

Conflicts of Interest

The authors have no conflicts to disclose.

Acknowledgements

This work was supported by National Natural Science Foundation of China (Grant NO. 82274186 to XL); National Key Research and Development Program on Modernization of Traditional Chinese Medicine (Grant NO. 2022YFC3502100 to XL); National High-Level Talents Special Support Program to XL.

Abbreviations

LSECs

liver sinusoidal endothelial cells

NO

nitric oxide

PLVAP

plasmalemma vesicle-associated protein

PDIA1

protein disulfide isomerase A1

ECs

endothelial cells

Oit3

oncoprotein-induced transcript 3

scRNA-seq

single-cell RNA sequencing

MASH

metabolic dysfunction-associated steatohepatitis

References

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