Triple-helical recombinant humanized type I collagen promotes photodamaged skin repair via ECM remodeling and anti-inflammatory mechanisms

Nannan Wei; Yuchen Zhang; Wenjie Huang; Xinyu Tian; Linyan Yao; Jianxi Xiao

doi:10.1186/s42825-026-00245-w

Collagen and Leather ›› 2026, Vol. 8 ›› Issue (1) :23 DOI: 10.1186/s42825-026-00245-w

Research

research-article

Triple-helical recombinant humanized type I collagen promotes photodamaged skin repair via ECM remodeling and anti-inflammatory mechanisms

Nannan Wei ¹^,²
, Yuchen Zhang ¹^,²
, Wenjie Huang ¹^,²
, Xinyu Tian ¹^,²
, Linyan Yao ²^,³
, Jianxi Xiao ¹^,²^,^a

Author information +

History +

PDF

Abstract

Ultraviolet (UV) irradiation is a major cause of photoaging, driving oxidative stress, inflammation, and extracellular matrix (ECM) degradation. Collagen is central to dermal integrity, yet animal-derived sources pose immunogenic and pathogen risks, while recombinant collagens reported to date often lack the stable triple-helical architecture required for bioactivity. Here, we present a triple-helical recombinant humanized type I collagen (THRCI) that combines native-like conformation with excellent biosafety and regenerative efficacy. THRCI supported fibroblast adhesion, proliferation, migration, and collagen synthesis, while suppressing intracellular reactive oxygen species and pro-inflammatory cytokines. In zebrafish, THRCI reduced oxidative stress and alleviated UV-induced caudal fin atrophy. In a murine model of acute UV photodamage, topical THRCI accelerated epidermal recovery, restored hydration and barrier function, increased dermal density, and promoted collagen fiber remodeling, while downregulating IL-6, IL-1β, MMP-1, and MMP-9. Collectively, these findings indicate that THRCI exhibits effective photodamage-repair properties in our established models and represents a promising animal-free collagen biomaterial for skin regeneration.

Graphical Abstract

Keywords

Recombinant humanized type I collagen / Triple-helix structure / Photodamage repair

Cite this article

Download citation ▾

Nannan Wei, Yuchen Zhang, Wenjie Huang, Xinyu Tian, Linyan Yao, Jianxi Xiao. Triple-helical recombinant humanized type I collagen promotes photodamaged skin repair via ECM remodeling and anti-inflammatory mechanisms. Collagen and Leather, 2026, 8 (1) : 23 DOI:10.1186/s42825-026-00245-w

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Lv X, Han Z, Huo H, Liu X, Zhang J, Chi J, Han B, Jiang Z. Anti-inflammatory and antioxidant succinyl-chitosan oligosaccharide protects human epidermal cell and mouse skin against ultraviolet B-induced photodamage. Carbohydr Polym, 2025, 351. ArticleID: 123102

[2]	Zhao H-C, Xiao T, Chen Y-J. Ultraviolet induced skin inflammation. Int J Dermatol Venereol, 2021, 4: 229-35.

[3]	Wang S, Yang M, Yin S, Zhang Y, Zhang Y, Sun H, Shu L, Liu Y, Kang Z, Liu N, Li J, Wang Y, He L, Luo M, Yang X. A new peptide originated from amphibian skin alleviates the ultraviolet B-induced skin photodamage. Biomed Pharmacother, 2022, 150. ArticleID: 112987

[4]	Chavda VP, Acharya D, Hala V, Daware S, Vora LK. Sunscreens: a comprehensive review with the application of nanotechnology. J Drug Deliv Sci Technol, 2023, 86. ArticleID: 104720

[5]	Azevedo Martins TE, de Sales Oliveira Pinto CA, de Costa Oliveira A, Robles Velasco MV, Gorriti Guitiérrez AR, Cosquillo Rafael MF, Tarazona JP, Retuerto-Figueroa MG. Contribution of topical antioxidants to maintain healthy skin-a review. Sci Pharm, 2020, 88. ArticleID: 27

[6]	Chen L, Hu JY, Wang SQ. The role of antioxidants in photoprotection: a critical review. J Am Acad Dermatol, 2012, 67: 1013-24.

[7]	Brar G, Dhaliwal A, Brar AS, Sreedevi M, Ahmadi Y, Irfan M, Golbari R, Zumárraga D, Yateem D, Lysak Y, Abarca-Pineda YA. A comprehensive review of the role of UV radiation in photoaging processes between different types of skin. Cureus, 2025, 17: e81109

[8]	Lo S, Fauzi MB. Current update of collagen nanomaterials-fabrication, characterisation and its applications: a review. Pharmaceutics, 2021, 13. ArticleID: 316

[9]	Kirkness MWH, Lehmann K, Forde NR. Mechanics and structural stability of the collagen triple helix. Curr Opin Chem Biol, 2019, 53: 98-105.

[10]	Gelse K, Pöschl E, Aigner T. Collagens-structure, function, and biosynthesis. Adv Drug Deliv Rev, 2003, 55: 1531-46.

[11]	Amirrah IN, Lokanathan Y, Zulkiflee I, Wee MFMR, Motta A, Fauzi MB. A comprehensive review on collagen type I development of biomaterials for tissue engineering: from biosynthesis to bioscaffold. Biomedicines, 2022, 10. ArticleID: 2307

[12]	Bielajew BJ, Hu JC, Athanasiou KA. Collagen: quantification, biomechanics, and role of minor subtypes in cartilage. Nat Rev Mater, 2020, 5: 730-747.

[13]	Meganathan I, Pachaiyappan M, Aarthy M, Radhakrishnan J, Mukherjee S, Shanmugam G, You J, Ayyadurai N. Recombinant and genetic code expanded collagen-like protein as a tailorable biomaterial. Nat Rev Mater, 2022, 9: 2698-721

[14]	Guo X-O, Ma Y, Wang H, Yin H, Shi X, Chen Y, Gao G, Sun L, Wang J, Wang Y, Fan D. Status and developmental trends in recombinant collagen preparation technology. Regen Biomater, 2023, 11. ArticleID: rbad106

[15]	He H, Wei N, Xie Y, Wang L, Yao L, Xiao J. Self-assembling triple-helix recombinant collagen hydrogel enriched with tyrosine. ACS Biomater Sci Eng, 2024, 10: 3268-79.

[16]	Wang L, Zhang S, Yang F, Chen X, He H, Liu Z, Xiao J. Bioactive poly (ethylene glycol)-chondroitin sulfate-triple helical recombinant collagen hydrogel for enhanced cranial defect repair. Collagen Leather, 2024, 6: 26.

[17]	Geddis AE, Prockop DJ. Expression of human COL1A1 gene in stably transfected HT1080 cells: the production of a thermostable homotrimer of type I collagen in a recombinant system. Matrix, 1993, 13: 399-405.

[18]	Toman PD, Chisholm G, McMullin H, Giere LM, Olsen DR, Kovach RJ, Leigh SD, Fong BE, Chang R, Daniels GA, Berg RA, Hitzeman RA. Production of recombinant human type I procollagen trimers using a four-gene expression system in the yeast Saccharomyces cerevisiae. J Biol Chem, 2000, 275: 23303-9.

[19]	Nokelainen M, Tu H, Vuorela A, Notbohm H, Kivirikko KI, Myllyharju J. High-level production of human type I collagen in the yeast Pichia pastoris. Yeast, 2001, 18: 797-806.

[20]	Zhang Y, Fu R, Zhu C, Yuwen W, Zhang J, Duan Z, Fan D. Preparation of recombinant type I collagen (PF-I-80) and its functional characterization and biomedical applications in wound healing. J Biol Chem, 2024, 282: 136679

[21]	Ruggiero F, Exposito JY, Bournat P, Gruber V, Perret S, Comte J, Olagnier B, Garrone R, Theisen M. Triple helix assembly and processing of human collagen produced in transgenic tobacco plants. FEBS Lett, 2000, 469: 132-6.

[22]	Merle C, Perret S, Lacour T, Jonval V, Hudaverdian S, Garrone R, Ruggiero F, Theisen M. Hydroxylated human homotrimeric collagen I in Agrobacterium tumefaciens-mediated transient expression and in transgenic tobacco plant. FEBS Lett, 2002, 515: 114-8.

[23]	Xu X, Gan Q, Clough RC, Pappu KM, Howard JA, Baez JA, Wang K. Hydroxylation of recombinant human collagen type I alpha 1 in transgenic maize co-expressed with a recombinant human prolyl 4-hydroxylase. BMC Biotechnol, 2011, 11. ArticleID: 69

[24]	Buechter DD, Paolella DN, Leslie BS, Brown MS, Mehos KA, Gruskin EA. Co-translational incorporation of trans-4-hydroxyproline into recombinant proteins in bacteria. J Biol Chem, 2003, 278: 645-50.

[25]	Yao J, Yanagisawa S, Asakura T. Design, expression and characterization of collagen-like proteins based on the cell adhesive and crosslinking sequences derived from native collagens. J Biochem, 2004, 136: 643-649.

[26]	Tolia NH, Joshua-Tor L. Strategies for protein coexpression in Escherichia coli. Nat Methods, 2006, 3: 55-64.

[27]	Liu S, Li Y, Wang M, Ma Y, Wang J. Efficient coexpression of recombinant human fusion collagen with prolyl 4-hydroxylase from Bacillus anthracis in Escherichia coli. Biotechnol Appl Biochem, 2023, 70: 761-772.

[28]	Tang Y, Yang X, Hang B, Li J, Huang L, Huang F, Xu Z. Efficient production of hydroxylated human-like collagen via the co-expression of three key genes in Escherichia coli Origami (DE3). Appl Biochem Biotechnol, 2016, 178: 1458-1470.

[29]	Wang N, Li Y, Han C, Ma Y, Liu Q, Sun L, Wang Y, Zhang H. Optimized prolyl-4-hydroxylase expression in Komagataella phaffii enables efficient triple-helix formation of recombinant human collagen. Biotechnol Bioeng, 2025, 122: 3406-3417.

[30]	Yang X, Yao L, Sun X, Wang L, Xiao J. Low-temperature DLP 3D printing of low-concentration collagen methacryloyl for the fabrication of durable and bioactive personalized scaffolds. Chem Eng J, 2024, 497. ArticleID: 155650

[31]	Bai M, Kang N, Xu Y, Wang J, Shuai X, Liu C, Jiang Y, Du Y, Gong P, Lin H, Zhang X. The influence of tag sequence on recombinant humanized collagen (rhCol) and the evaluation of rhCol on Schwann cell behaviors. Regen Biomater, 2023, 10. ArticleID: rbad089

[32]	Wang J, Hu H, Wang J, Qiu H, Gao Y, Xu Y, Liu Z, Tang Y, Song L, Ramshaw J, Lin H, Zhang X. Characterization of recombinant humanized collagen type III and its influence on cell behavior and phenotype. J Leather Sci Eng, 2022, 4. ArticleID: 33

[33]	Fu C, Shi S, Wei N, Fan Y, Gu H, Liu P, Xiao J. Biocompatible triple-helical recombinant collagen dressings for accelerated wound healing in microneedle-injured and photodamaged skin. Cosmetics, 2023, 10. ArticleID: 31

[34]

Pien N, Di Francesco D, Copes F, Bartolf-Kopp M, Chausse V, Meeremans M, Pegueroles M, Jüngst T, De Schauwer C, Boccafoschi F, Dubruel P, Van Vlierberghe S, Mantovani D. Polymeric reinforcements for cellularized collagen-based vascular wall models: influence of scaffold architecture on mechanical and biological properties. Front. Bioeng. Biotechnol, 2023, 11. ArticleID: 1285565

[35]

Xie J, Liu G, Chen R, Wang D, Mai H, Zhong Q, Ning Y, Fu J, Tang Z, Xu Y, Li H, Lei M, Cheng H, Huang Y, Zhang Y. NIR-activated electrospun nanodetonator dressing enhances infected diabetic wound healing with combined photothermal and nitric oxide-based gas therapy. J. Nanobiotechnol, 2024, 22. ArticleID: 232

[36]	Liu X, Zhang R, Shi H, Li X, Li Y, Taha A, Xu C. Protective effect of curcumin against ultraviolet A irradiation-induced photoaging in human dermal fibroblasts. Mol Med Rep, 2018, 17: 7227-37

[37]	Wang L, Li J, Zhang Y, Zhu Z, Gao R. Recombinant human collagen digestates exhibit higher protective effect on UVA-damaged skin fibroblasts than animal-derived collagens. J. Funct. Foods, 2024, 113. ArticleID: 106035

[38]	Lee SH, Jeong YM, Kim SY, Jeong HS, Park KC, Baek KJ, Kwon NS, Yun HY, Kim DS. Ultraviolet B-induced LGI3 secretion protects human keratinocytes. Exp Dermatol, 2012, 21: 710-20.

[39]	Hansen U, Bruckner P. Fibrils of collagens I and XI contain a heterotypic alloyed core and a collagen I sheath. J Biol Chem, 2003, 278: 37352-9.

[40]	Ye M, Fan Y, Fu C, He H, Xiao J. Biocompatible recombinant type III collagen enhancing skin repair and anti-wrinkle effects. Biomater Sci, 2024, 12: 6114-22.

[41]	Gahlawat S, Nanda V, Shreiber DI. Purification of recombinant bacterial collagens containing structural perturbations. PLoS One, 2023, 18(5): e0285864.

[42]	Seo N, Russell BH, Rivera JJ, Liang X, Xu X, Afshar-Kharghan V, Höök M. An engineered alpha1 integrin-binding collagenous sequence. J Biol Chem, 2010, 285: 31046-54.

[43]	Monika P, Waiker PV, Chandraprabha MN, Rangarajan A, Murthy KNC. Myofibroblast progeny in wound biology and wound healing studies. Wound Repair Regen, 2021, 29: 531-47.

[44]	Li G, Li Y-Y, Sun J-E, Lin W-H, Zhou R-X. ILK-PI3K/AKT pathway participates in cutaneous wound contraction by regulating fibroblast migration and differentiation to myofibroblast. Lab Invest, 2016, 96: 741-51.

[45]	Cavinato M, Jansen-Dürr P. Molecular mechanisms of UVB-induced senescence of dermal fibroblasts and its relevance for photoaging of the human skin. Exp. Gerontol., 2017, 94: 78-82.

[46]	Battie C, Jitsukawa S, Bernerd F, Del Bino S, Marionnet C, Verschoore M. New insights in photoaging, UVA induced damage and skin types. Exp. Dermatol., 2014, 1: 7-12.

[47]	Li Q, Wang P, Wang C, Hu B, Wang X, Li D. Benzotriazole UV stabilizer-induced genotoxicity in freshwater benthic clams: a survey on apoptosis, oxidative stress, histopathology and transcriptomics. Sci. Total Environ., 2023, 857. ArticleID: 159055

[48]	Liu T, Zhang D, Pan Z, Yang H, Ruan B, Bo Y, Xie L, Wang Z, Zhang J. Lysine-based ionic liquid enables peptides to reverse skin photoaging: from leaves to roots. Adv. Funct. Mater., 2023, 33. ArticleID: 2300723

[49]	Qiang M, Xu Y, Lu Y, He Y, Han C, Liu Y, He R. Autofluorescence of MDA-modified proteins as an and probe in oxidative stress analysis.. Protein Cell, 2014, 5: 484-487.

[50]	Zhang P, Liu N, Xue M, Zhang M, Liu W, Xu C, Fan Y, Meng Y, Zhang Q, Zhou Y. Anti-inflammatory and antioxidant properties of β-sitosterol in copper sulfate-induced inflammation in zebrafish (Danio rerio). Antioxidants, 2023, 12: 391.

[51]

Singh M, Guru A, Sudhakaran G, Pachaiappan R, Mahboob S, Al-Ghanim KA, Al-Misned F, Juliet A, Gobi M, Arokiaraj J. Copper sulfate induced toxicological impact on in-vivo zebrafish larval model protected by acacetin via anti-inflammatory and glutathione redox mechanism. Comp Biochem Physiol C Toxicol Pharmacol, 2022, 262. ArticleID: 109463

[52]	Fu F, Zuo X, Wang Y, Zhao F, Li C, Zeng Y, Wang L, Wang F. Centrifugal spinning-derived biomimetic aerogel for rapid hemostasis with minimal blood loss. Nano Lett, 2025, 25: 6040-50.

[53]	Wang Y-J, Chang C-C, Lu M-E, Wu Y-H, Shen J-W, Chiang H-M, Lin B-S. Photoaging and sequential function reversal with cellular-resolution optical coherence tomography in a nude mice model. Int J Mol Sci, 2022, 23: 7009.

[54]	Schoenfelder H, Liu Y, Lunter DJ. Systematic investigation of factors, such as the impact of emulsifiers, which influence the measurement of skin barrier integrity by in- trans-epidermal water loss (TEWL). Int J Pharm, 2023, 638. ArticleID: 122930

[55]	Zhou Q, Dai H, Yan Y, Qin Z, Zhou M, Zhang W, Zhang G, Guo R, Wei X. From short circuit to completed circuit: conductive hydrogel facilitating oral wound healing. Adv Healthc Mater, 2024, 13. ArticleID: 2303143

[56]	Liu Y, Yang X, Wu K, Feng J, Zhang X, Li A, Cheng C, Zhu YZ, Guo H, Wang X. Skin-inspired and self-regulated hydrophobic hydrogel for diabetic wound therapy. Adv Mater, 2025, 37. ArticleID: 2414989

[57]

Mujtaba AG, Karakeçili A, Topuz B, Batur B, Onar O, Elçiğir ME, Oto Ç, Hanifehnezhad A, Orhan K. Tri-layered bioactive cutaneous scaffold with integrated bioactive metal organic frameworks to promote full-thickness infected diabetic wound healing: multifaceted therapeutic strategies. Adv Healthc Mater, 2025, 14. ArticleID: 2500356

[58]	Ma H, Luo Y, Wang Y, Hao Y, Li J, Gao X, Xiong Y, He L. Artificial multienzyme nanoflower composite hydrogel for efficiently promoting MRSA-infected diabetic wound healing via glucose-activated NO releasing and microenvironment regulation. Bioact Mater, 2025, 49: 531-48