Lysyl hydroxylase 2 glucosylates collagen VI to drive lung cancer progression
Shike Wang, … , Xiaochao Tan, Jonathan M. Kurie
Shike Wang, … , Xiaochao Tan, Jonathan M. Kurie
Published April 1, 2025
Citation Information: J Clin Invest. 2025;135(7):e189197. https://doi.org/10.1172/JCI189197.
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Research Article Cell biology Oncology

Lysyl hydroxylase 2 glucosylates collagen VI to drive lung cancer progression

Abstract

Lysyl hydroxylase 2 (LH2) is highly expressed in multiple tumor types and accelerates disease progression by hydroxylating lysine residues on fibrillar collagen telopeptides to generate stable collagen cross links in tumor stroma. Here, we show that a galactosylhydroxylysyl glucosyltransferase (GGT) domain on LH2 modified type-VI collagen (Col6) to promote lung adenocarcinoma (LUAD) growth and metastasis. In tumors generated by LUAD cells lacking LH2 GGT domain activity, stroma was less stiff, and stable types of collagen cross links were reduced. Mass spectrometric analysis of total and glycosylated peptides in parental and GGT-inactive tumor samples identified Col6 chain α3 (Col6a3), a component of the Col6 heterotrimeric molecule, as a candidate LH2 substrate. In gain- and loss-of-function studies, high Col6a3 levels increased tumor growth and metastatic activity and enhanced the proliferative, migratory, and invasive activities of LUAD cells. LH2 coimmunoprecipitated with Col6a3, and LH2 glucosylated Col6 in an in vitro reaction. Glucosylation increased the integrin-binding and promigratory activities of Col6 in LUAD cells. Col6a3 K2049 was deglucosylated in GGT-inactive tumor samples, and mutagenesis of Col6a3 K2049 phenocopied Col6a3 deficiency or LH2 GGT domain inactivation in LUAD cells. Thus, LH2 glucosylates Col6 to drive LUAD progression. These findings show that the GGT domain of LH2 is protumorigenic, identify Col6 as a candidate effector, and provide a rationale to develop pharmacological strategies that target LH2’s GGT domain in cancer cells.

Authors

Shike Wang, Houfu Guo, Reo Fukushima, Masahiko Terajima, Min Liu, Guan-Yu Xiao, Lenka Koudelková, Chao Wu, Xin Liu, Jiang Yu, Emma Burris, Jun Xu, Alvise Schiavinato, William K. Russell, Mitsuo Yamauchi, Xiaochao Tan, Jonathan M. Kurie

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Figure 4

Glucosylation enhances the cell biological activities of Col6.

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Glucosylation enhances the cell biological activities of Col6. (A) IP/WB...
(A) IP/WB analysis of H157 cells transfected with Flag-tagged LH2. Col6a3 coimmunoprecipitated with HA-tagged LH2. The LH2 chaperone FKBP65 included as a positive control. Total cell lysates (input). (B) In vitro GGT activity assay on purified LH2 reacted with PGGHG-pretreated Col6 as substrate. Each dot represents a replicate reaction. (C and D) Boyden chamber migration assays. 344P cells were seeded on membranes coated with Col6, PGGHG-pretreated Col6 (deglu-Col6), or BSA. Migrated cells were imaged (C) and quantified (D). (E) Immunocytochemical detection of activated ITGβ1 (arrows) in 344SQ cells. Scale bar 50 μm. (F) Quantification of activated ITGβ1 per cell (dot). (G) WB analysis of 344SQ cells. Densitometric quantification of p-FAK normalized based on total FAK (values under gel). (H) Boyden chamber migration assay on 344SQ cells treated with ITGα2 inhibitor TC-I 15 in the presence of soluble Col6 or BSA. (I) Scratch wound closure rates for control (NC) and CA-Col6a3 H358 cells in the presence or absence of TC-I 15. (J and K) Boyden chamber migration assays on 344SQ cells treated with neutralizing antibodies against ITGβ1 (J) or ITGα2 (K) followed by soluble Col6 or BSA. (L and M) Boyden chamber migration assays on shITGβ1- (L) or siITGα2- (M) transfected 344SQ cells treated with soluble Col6 or BSA. (N) Quantification of activated ITGβ1 per cell (dot). 344SQ cells were seeded on surfaces coated with BSA, Col6, or PGGHG-treated Col6 (deglu-Col6) and immunostained with anti-activated ITGβ1 antibody. (O) Solid phase binding assays on purified ITGα2/β1 heterodimers incubated with PGGHG-treated (deglu-Col6) or untreated Col6. P values were determined using 1-way ANOVA (B, D, F, and HN) or 2-way ANOVA (O).