A Preconditioning Strategy to Augment Retention and Engraftment Rate of Donor Cells During Hepatocyte Transplantation

Intracellular autoactivation and surface location of hepsin, TMPRSS2, and TMPRSS13

AIMS

Hepsin (HPN), a Type II transmembrane serine protease (TTSP), is involved in hepatocyte metabolism and various diseases. It undergoes autoactivation on the surface of human hepatoma cells, a mechanism not observed in other cell types. This study aims to explore HPN activation and surface expression in endometrial epithelial cells.

MATERIALS AND METHODS

We studied HPN zymogen activation and cell surface expression in human embryonic kidney 293 and endometrial epithelial AN3CA and Ishikawa cells using site-directed mutagenesis, Western blotting, flow cytometry, and immunostaining. Treatments with brefeldin A (BFA) and monensin, along with co-transfection assays, were employed to assess HPN activation and expression before reaching the cell surface. We also analyzed the activation and expression of TMPRSS2 and TMPRSS13 and examined the effect of the serine protease inhibitor HAI-1 on these proteases.

KEY FINDINGS

HPN zymogen autoactivates in the endoplasmic reticulum (ER) and Golgi apparatus. Its active form reduces cell surface expression through trans-autodegradation, a mechanism also applicable to in TMPRSS2 and TMPRSS13. Additionally, HAI-1 interacts with these TTSPs in different ways: it inhibits HPN activation and stabilizes its cell-surface expression; it inhibits TMPRSS2 activation without affecting its cell-surface expression; and it facilitates TMPRSS13 activation, protecting it from degradation and stabilizing its cell surface expression.

SIGNIFICANCE

These results revealed an intracellular autoactivation and expression mechanism of HPN, TMPRSS2, and TMPRSS13, differing from the extracellular activated TTSPs. These findings provide new insights into the diverse mechanisms in regulating TTSP activation, potentially aiding in treating TTSP-related endometrial diseases.

Host hepatocyte senescence determines the success of hepatocyte transplantation in a mouse model of liver injury

BACKGROUND & AIMS

Hepatocyte transplantation has shown promise for genetic diseases of the hepatocytes but to date has shown limited efficacy for non-genetic forms of severe liver injury. Limited cell engraftment and poor function of donor hepatocytes in recipient livers impacts the clinical utility of hepatocyte cell therapy. The mechanisms underpinning this are poorly understood. We explored this in a liver injury model, where predictable levels of injury and hepatocyte senescence were induced in AhCreMdm2fl/fl mice through genetic excision of hepatocyte Mdm2.

METHODS

Freshly isolated mouse or human cryopreserved hepatocytes were delivered via intrasplenic injection into AhCreMdm2fl/fl (immune competent and deficient strains) mice. Engraftment kinetics, donor cell engraftment and host liver function were assessed. Paired transcriptomic and proteomic analyses were performed on healthy vs. senescent mouse hepatocytes.

RESULTS

We found inhibition of host hepatocyte proliferation and liver injury is a requirement for donor hepatocyte engraftment and long-term repopulation, improving liver repair and function, but excessive senescence inhibited this process, causing a decline in graft function due to transmission of senescence from host to donor cells. Paired proteomic and transcriptomic analyses of healthy vs. senescent hepatocytes reveal a unique senescent signature associated with paracrine senescence. Modification of the host niche prior to transplantation with the senotherapeutic drug ABT737 improved donor cell proliferative capacity.

CONCLUSIONS

The host niche impacts the initial engraftment and long-term function of transplanted hepatocytes. Targeting paracrine senescence may be a way to improve donor hepatocyte function, optimise therapy and guide translation into the clinic.

IMPACT AND IMPLICATIONS

Hepatocyte transplantation has shown promise for genetic diseases but has limited efficacy for acute and severe liver injury. Poor engraftment and functionality have prevented large-scale clinical application. We show that host senescence provides the required non-competitive niche for donor hepatocytes to repopulate the recipient liver, but can, paradoxically, negatively impact donor function. These findings demonstrate a requirement for a clear understanding of the host niche prior to cell transfusion. This has significant implications not only for hepatocellular therapies, but also when developing and optimising any preclinical and clinical cell therapies.

Enhancement of adult liver regeneration in mice through the hepsin-mediated epidermal growth factor receptor signaling pathway

Given the widespread use of partial hepatectomy for treating various liver pathologies, understanding the mechanisms of liver regeneration is vital for enhancing liver resection and transplantation therapies. Here, we demonstrate the critical role of the serine protease Hepsin in promoting hepatocyte hypertrophy and proliferation. Under steady-state conditions, liver-specific overexpression of Hepsin in adult wild-type mice triggers hepatocyte hypertrophy and proliferation, significantly increasing liver size. This effect is predominantly driven by the catalytic activity of Hepsin, engaging the EGFR-Raf-MEK-ERK signaling pathway. Significantly, administering Hepsin substantially enhances hepatocyte proliferation and facilitates liver regeneration following a 70% partial hepatectomy. Crucially, the proliferation induced by Hepsin is a transient event, without leading to long-term adverse effects such as liver fibrosis or hepatocellular carcinoma, as evidenced by extensive observation. These results offer substantial potential for future clinical applications and translational research endeavors in the field of liver regeneration post-hepatectomy.

Type II Transmembrane Serine Proteases as Modulators in Adipose Tissue Phenotype and Function

Adipose tissue is a crucial organ in energy metabolism and thermoregulation. Adipose tissue phenotype is controlled by various signaling mechanisms under pathophysiological conditions. Type II transmembrane serine proteases (TTSPs) are a group of trypsin-like enzymes anchoring on the cell surface. These proteases act in diverse tissues to regulate physiological processes, such as food digestion, salt-water balance, iron metabolism, epithelial integrity, and auditory nerve development. More recently, several members of the TTSP family, namely, hepsin, matriptase-2, and corin, have been shown to play a role in regulating lipid metabolism, adipose tissue phenotype, and thermogenesis, via direct growth factor activation or indirect hormonal mechanisms. In mice, hepsin deficiency increases adipose browning and protects from high-fat diet-induced hyperglycemia, hyperlipidemia, and obesity. Similarly, matriptase-2 deficiency increases fat lipolysis and reduces obesity and hepatic steatosis in high-fat diet-fed mice. In contrast, corin deficiency increases white adipose weights and cell sizes, suppresses adipocyte browning and thermogenic responses, and causes cold intolerance in mice. These findings highlight an important role of TTSPs in modifying cellular phenotype and function in adipose tissue. In this review, we provide a brief description about TTSPs and discuss recent findings regarding the role of hepsin, matriptase-2, and corin in regulating adipose tissue phenotype, energy metabolism, and thermogenic responses.

Hepsin: a multifunctional transmembrane serine protease in pathobiology

Cell membrane-bound serine proteases are important in the maintenance of physiological homeostasis. Hepsin is a type II transmembrane serine protease highly expressed in the liver. Recent studies indicate that hepsin activates prohepatocyte growth factor in the liver to enhance Met signaling, thereby regulating glucose, lipid, and protein metabolism. In addition, hepsin functions in nonhepatic tissues, including the adipose tissue, kidney, and inner ear, to regulate adipocyte differentiation, urinary protein processing, and auditory function, respectively. In mouse models, hepsin deficiency lowers blood glucose, lipid, and protein levels, impairs uromodulin assembly in renal epithelial cells, and causes hearing loss. Elevated hepsin expression has also been found in many cancers. As a type II transmembrane protease, cell surface expression and zymogen activation are essential for hepsin activity. In this review, we discuss the current knowledge regarding hepsin biosynthesis, activation, and functions in pathobiology.