Expression of collagen type IV in human kidney during prenatal development
Abstract
Background/Aim. Type IV collagen belongs to the group of nonfibrillar collagens and is an important component of the basement membranes, where it accounts for approximately 50% of its structural elements. The aim of the study was to describe the expression and distribution of collagen type IV in the embryonic and fetal metanephric kidney and to determine the volume density of collagen type IV in kidney tissue in each trimester of development. Methods. The material consisted of 19 human embryos/fetuses, in the gestational age from 8th to 37th week. Kidney tissue specimens were routinely processed to paraffin molds, stained immunohistochemically using polyclonal anti-collagen IV antibody and counterstained with Mayer hematoxylin and eosin. Stained slides were examined using a light microscope, and images of the selected areas under different lens magnification were captured with a digital camera. Volume density of collagen type IV was determined using ImageJ 1.48v and a plugin of the software, which inserted a grid system with 336 points. For the data comparison, the One-Way Analysis of Variance (ANOVA) was used. Results. Strong collagen IV immunopositivity was seen in all specimens, with a distribution in the basement membranes of urinary bud, parietal leaf of Bowman’s capsule, glomerular basement membrane, basement membrane of interstitial blood vessels, and basement membranes of nephron tubules and collecting ducts. No statistically significant difference in the volume density of type IV collagen was found among the different trimesters of the embryonic and fetal development. Conclusion. The synthesis and secretion of collagen type IV simultaneously follow the development of nephron structures, collecting system and blood vessels. The volume density of collagen type IV remains constant throughout all the trimesters of metanephric kidney development, indicating that it plays a crucial role in the normal development of nephron and collecting system structures, as well as in maintaining the normal kidney function.
References
1. Quaggin SE, Kreidberg JA. Development of the renal glomeru-lus: good neighbors and good fences. Development 2008; 135(4): 609‒20.
Murawski IJ, Maina RW, Gupta IR. The relationship between nephron number, kidney size and body weight in two inbred mouse strains. Organogenesis 2010; 6(3): 189‒94.
Costantini F, Kopan R. Patterning a complex organ: branching morphogenesis and nephron segmentation in kidney develop-ment. Dev Cell 2010; 18(5): 698‒712.
Schoenwolf G, Bleyl S, Brauer P, Francis-West P. Larsen’s human embryology. 4th ed. Philadelphia: Churchill Livingston, Else-vier; 2009.
Reidy KJ, Rosenblum ND. Cell and molecular biology of kidney development. Semin Nephrol 2009; 29(4): 321‒37.
Little MH, Combes AN. Kidney organoids: accurate models or fortunate accidents. Genes Dev 2019; 33(19‒20): 1319‒45.
Dressler GR. The cellular basis of kidney development. Annu Rev Cell Dev Biol 2006; 22: 509‒29.
Costantini F, Shakya R. GDNF/Ret signaling and the devel-opment of the kidney. Bioessays 2006; 28(2): 117‒27.
Nagalakshmi VK, Yu J. The ureteric bud epithelium: morpho-genesis and roles in metanephric kidney patterning. Mol Re-prod Dev 2015; 82(3): 151‒66.
Kobayashi A, Mugford JW, Krautzberger AM, Naiman N, Liao J, McMahon AP. Identification of a multipotent self-renewing stromal progenitor population during mammalian kidney or-ganogenesis. Stem Cell Reports 2014; 3(4): 650‒62.
Hudson BG, Reeders ST, Tryggvason K. Type IV collagen: Struc-ture, gene organization, and role in human diseases—Molecular basis of Goodpasture and Alport syndromes and diffuse leiomyomatosis. J Biol Chem 1993; 268(35): 26033‒6.
Kalluri R. Basement membranes: structure, assembly and role in tumour angiogenesis. Nat Rev Cancer 2003; 3(6): 422‒33.
Chioran A, Duncan S, Catalano A, Brown TJ, Ringuette MJ. Colla-gen IV trafficking: The inside-out and beyond story. Dev Biol 2017; 431(2): 124‒33.
Cosgrove D, Liu S. Collagen IV diseases: A focus on the glo-merular basement membrane in Alport syndrome. Matrix Biol 2017; 57‒58: 45‒54.
Timpl R, Brown JC. Supramolecular assembly of basement membranes. Bioessays 1996; 18(2): 123‒32.
Johansson C, Butkowski R, Wieslander J. The structural organiza-tion of type IV collagen: Identification of three NC1 popula-tions in the glomerular basement membrane. J Biol Chem 1992; 267(34): 24533‒7.
Mak KM, Mei R. Basement Membrane Type IV Collagen and Laminin: An Overview of Their Biology and Value as Fibrosis Biomarkers of Liver Disease. Anat Rec (Hoboken) 2017; 300(8): 1371‒90.
Kališnik M, Eržen I, Smolej V. Stereološke metode. In: Kališnik M, editor. Temelji stereologije. 3rd ed. Ljubljana: DSKAS; 2002.
Abrahamson DR. Development of kidney glomerular endothe-lial cells and their role in basement membrane assembly. Or-ganogenesis 2009; 5(1): 275‒87.
Abrahamson DR. Structure and development of the glomerular capillary wall and basement membrane. Am J Physiol 1987; 253(5 Pt 2): F783‒94.
Lelongt B, Makino H, Kanwar YS. Maturation of the developing renal glomerulus with respect to basement membrane proteo-glycans. Kidney Int 1987; 32(4): 498–506.
Alexakis C, Maxwell P, Bou-Gharios G. Organ-specific collagen expression: implications for renal disease. Nephron Exp Nephrol 2006; 102(3‒4): e71‒5.
Abrahamson DR, Leardkamolkarn V. Development of kidney tubular basement membranes. Kidney Int 1991; 39(3): 382‒93.
Pozzi A, Yurchenco PD, Iozzo RV. The nature and biology of basement membranes. Matrix Biol 2017; 57‒58: 1‒11.
Lelongt B, Ronco P. Role of extracellular matrix in kidney de-velopment and repair. Pediatr Nephrol 2003; 18(8): 731‒42.
Miner JH, Sanes JR. Molecular and functional defects in kid-neys of mice lacking collagen alpha 3(IV): implications for Al-port syndrome. J Cell Biol 1996; 135(5): 1403‒13.
Monaghan P, Warburton MJ, Perusinghe N, Rudland PS. Topo-graphical arrangement of basement membrane proteins in lac-tating rat mammary gland: comparison of the distribution of type IV collagen, laminin, fibronectin, and Thy-1 at the ultra-structural level. Proc Natl Acad Sci U S A 1983; 80(11): 3344‒8.
Sasaki H, Kishiye T, Fujioka A, Shinoda K, Nagano M. Effects of extracellular matrix macromolecules on the differentiation of plasma membrane structure in cultured astrocytes. Cell Struct Funct 1996; 21(2): 133‒41.
Lohi J, Korhonen M, Leivo I, Kangas L, Tani T, Kalluri R, et al. Expression of type IV collagen alpha1(IV)-alpha6(IV) poly-peptides in normal and developing human kidney and in renal cell carcinomas and oncocytomas. Int J Cancer 1997; 72(1): 43‒9.
Miner JH. Developmental biology of glomerular basement membrane components. Curr Opin Nephrol Hypertens 1998; 7(1): 13‒9.
Abrahamson DR, St John PL, Stroganova L, Zelenchuk A, Steen-hard BM. Laminin and type IV collagen isoform substitutions occur in temporally and spatially distinct patterns in develop-ing kidney glomerular basement membranes. J Histochem Cy-tochem 2013; 61(10): 706‒18.
Nagata M. Glomerulogenesis and the role of endothelium. Curr Opin Nephrol Hypertens 2018; 27(3): 159‒64.
Abrahamson DR. Role of the podocyte (and glomerular endo-thelium) in building the GBM. Semin Nephrol 2012; 32(4): 342‒9.
Miner JH. Renal basement membrane components. Kidney Int 1999; 56(6): 2016‒24.
Jalali M, Nikravesh MR, Moeen AA, Karimfar MH, Saidinejat S, Mohammadi S, et al. Inductive role of collagen type IV during nephrogenesis in mice. Urol J 2009; 6(4): 289‒94.
Khoshnoodi J, Pedchenko V, Hudson BG. Mammalian collagen IV. Microsc Res Tech 2008; 71(5): 357‒70.
Funk SD, Lin MH, Miner JH. Alport syndrome and Pierson syndrome: Diseases of the glomerular basement mem-brane. Matrix Biol 2018; 71‒72: 250‒61.
Nozu K, Nakanishi K, Abe Y, Udagawa T, Okada S, Okamoto T, et al. A review of clinical characteristics and genetic back-grounds in Alport syndrome. Clin Exp Nephrol 2019; 23(2): 158‒68.
Thibaud V, Rioux-Leclercq N, Vigneau C, Morice S. Recurence of Goodpasture syndrome without circulating anti-glomerular basement membrane antibodies after kidney transplant, a case report. BMC Nephrol 2019; 20(1): 6.