Pathological diagnosis of Alport syndrome

Article information

Korean J Nephrol. 2024;.j.krcp.24.063
Publication date (electronic) : 2024 August 23
doi : https://doi.org/10.23876/j.krcp.24.063
1Department of Pathology, Seoul National University College of Medicine, Seoul, Republic of Korea
2Department of Pathology, Yonsei University College of Medicine, Seoul, Republic of Korea
Correspondence: Beom Jin Lim Department of Pathology, Yonsei University College of Medicine, 50-1 Yonsei-ro, Seodaemun-gu, Seoul 03722, Republic of Korea. E-mail: bjlim@yuhs.ac
Received 2024 March 6; Revised 2024 April 3; Accepted 2024 April 15.

Abstract

Alport syndrome (AS) is a hereditary nephritis characterized by structural abnormalities in the glomerular basement membrane resulting from pathogenic variants in the COL4A3, COL4A4, and COL4A5 genes. Conventional pathological evaluations reveal nonspecific light microscopic changes and diagnostic clues can be obtained through electron microscopy. Type IV collagen staining elucidates distinct patterns based on AS inheritance, aiding in subtype classification. However, limitations arise, particularly in autosomal dominant cases. Genetic testing, particularly next-generation sequencing, gains prominence due to its ability to identify diverse mutations within COL4A3, COL4A4, and COL4A5.

Introduction

Alport syndrome (AS) is a hereditary nephritis related to a structural abnormality of the glomerular basement membrane (GBM) caused by pathogenic variants in genes of α3, α4, and α5 chains of type IV collagen (COL4A3, COL4A4, and COL4A5, respectively). The clinical manifestation of AS includes various degrees of hematuria, proteinuria, progressive renal insufficiency, and, eventually, end-stage kidney disease [13].

This article will focus on the pathological diagnosis of AS, reviewing the variations in pathological findings according to the different inheritance modes of AS and pathological differential diagnoses. Also, the recent advances in genetic tests will be briefly summarized.

Pathophysiology of Alport syndrome

Type IV collagen is present in all basement membranes of the human body. Genes named COL4A1 to COL4A6 are responsible for encoding α1 to α6 isoforms of type IV collagen. These isoforms assemble into three kinds of heterotrimers composed of α1-α1-α2, α3-α4-α5, and α5-α5-α6, and then assemble together to form a meshwork network. In the kidney, α3-α4-α5 type IV collagen is present in the GBM and distal tubular basement membrane (TBM), and α5-α5-α6 type IV collagen is present in Bowman’s capsule, while α1-α1-α2 collagen is present in all the basement membranes [4,5]. AS results from the mutation of genes producing α3, α4, and α5 chains. Therefore, the proportion of the α1-α1-α2 heterotrimer increases in the kidneys of AS patients [6]. The mechanisms of the subsequent structural and functional changes in the glomeruli of AS patients have not been fully elucidated; however, clues are obtained from in vitro and animal model studies. The GBM composed of α1-α1-α2 collagen is mechanically less stable than the GBM composed of α3-α4-α5 trimer. Podocytes interact with intact α3-α4-α5 GBM via discoidin domain receptor 1 and integrin α2β1 to maintain the function of the slit diaphragm, and this interaction is altered in AS. Moreover, podocytes recognizing mutated collagen upregulate the production of profibrotic factors, proteolytic enzymes, and chemokines such as transforming growth factor-β and matrix metalloproteinases, resulting in structural alteration of the GBM [69].

Conventional pathological evaluation

Light microscopic findings of AS are not specific to the disease. Glomeruli show no significant change in the early phase. With the progression of the disease, glomerular capillary loops become irregularly thick, and segmental or global glomerulosclerosis occurs. Mesangial hypercellularity may also be observed not infrequently [10]. Tubulointerstitium also shows tubular atrophy and interstitial fibrosis, which can be seen in other chronic kidney diseases. While interstitial foam cells can be observed in various glomerular diseases such as immunoglobulin A (IgA) nephropathy, membranous nephropathy, and idiopathic focal segmental glomerulosclerosis (FSGS), they are more frequently observed in AS patients [11], and they are not always associated with nephrotic range proteinuria (Fig. 1) [12]. Conventional immunofluorescence, including IgG, IgA, IgM, C3, C4, and C1q, does not show specific deposits. Since no specific findings are observed under light and immunofluorescent microscopies, and in some cases, the diagnosis of AS cannot be suspected by clinical history, the first clue of the diagnosis is obtained by electron microscopy [13]. The earliest electron microscopic finding of AS is segmental thinning of the lamina densa. As the disease progresses, GBM irregularity increases showing lamellation, splitting, and scalloping of the lamina densa. In severe cases, so-called “basket weaving” occurs. The podocytes show various degrees of foot process effacement. Microparticles or spherules can be observed within the GBM (Fig. 2) [4,12,13]. Similar findings are present in pediatric cases [14]. The above findings may present in other glomerular diseases; particularly, incomplete lamellation of the GBM can often be challenging to distinguish from nonspecific GBM damage or alteration. Therefore, it is not possible to confirm AS through conventional pathological examinations, and their significance lies in providing clues for performing specific diagnostic tests for AS. The confirmatory tests include type IV collagen subtype staining and recently emerging genetic tests.

Figure 1.

Interstitial accumulation of foam cells (arrows) is frequently observed in Alport syndrome (periodic acid-Schiff stain, ×200).

Figure 2.

Electron microscopic findings of Alport syndrome.

The glomerular basement membrane (GBM) shows alternating thin and thick segments and frequent foot process effacement (A, ×3,000). In more progressed cases, the GBM shows marked irregularity with lamellation and scalloping of the lamina densa (B, ×20,000) and intramembranous microspherules (arrowheads) (C, ×8,000).

Type IV collagen staining in Alport syndrome

Immunofluorescent staining of α chain subtypes reveals different staining patterns according to the inheritance pattern of AS [4,5]. Male X-linked AS patients who have mutations of COL4A5 show no staining of α5 and α3 chains in GBM, distal TBM, and Bowman’s capsule, while heterozygote females show mosaic pattern staining of α5 collagen in the GBM [15]. In autosomal recessive homozygote AS associated with COL4A3, α3 collagen and α5 collagen, which are dependent on α3, are decreased in the GBM and distal TBM. In contrast to X-linked AS, α5 collagen stain is preserved in Bowman’s capsule [12]. Autosomal dominant AS usually shows normal pattern expression of the α5 chain [16]. Therefore, the diagnosis requires further examination, such as next-generation sequencing (NGS). A commonly employed approach in clinical settings involves staining only α2 chain and α5 chain antibodies. The expression of α2 is considered as a control, and the diagnosis is determined by the expression of α5 (Fig. 3) [17]. However, immunofluorescent staining results are significantly influenced by the causative gene, the extent of abnormality, and the mode of inheritance. Especially, autosomal dominant AS cannot be detected by collagen staining. Recently, there has been an increasing number of reports on cases with pathologic variants in both COL4A3 and COL4A5 (“digenic” AS) [18], highlighting the limitations of collagen staining even more.

Figure 3.

Immunofluorescent staining of collagen IV (×200).

Normal control tissue reveals both α2 chain stain (red) and α5 chain stain (green) along the glomerular basement membrane and Bowman’s capsule (A). Male X-linked Alport syndrome reveals complete loss of α5 chain (B), while female heterozygote Alport syndrome shows partial loss of α5 chain (C).

Genetic tests for Alport syndrome diagnosis

Due to the reasons mentioned above, genetic testing in diagnosing AS is becoming increasingly significant. The genetic mutations causing AS occur within COL4A3, COL4A4, and COL4A5, but due to the extensive diversity of these mutations, NGS has been recognized as the most suitable and widely used testing method. Consequently, this approach has led to the discovery of new types of previously unknown mutations [10,19,20]. For indications, strategies in using genetic tests, the clinical significance of specific mutations, interpretation of variants of uncertain significance, and other details on this topic, it is recommended to refer to specialized references that comprehensively cover these aspects [21].

Other glomerular diseases having genetic alterations of collagen type IV

The diagnosis of thin basement membrane disease (TBMD) requires diffuse thinning of the GBM without lamellation or basket weaving. The thickness of the GBM measured by electron microscopy varies depending on the tissue processing procedures, so each laboratory should establish its own standards. Generally, a 250 nm or less thickness in adults and in children, 180 nm or less may raise suspicion for TBMD [22]. The alternative term for TBMD, benign familial hematuria, is attributed to the perception of a favorable prognosis associated with TBMD. However, recent genetic studies have revealed that TBMD also harbors heterozygous mutations in COL4A3 or COL4A4, leading to its reclassification as part of the AS spectrum [23,24].

Some cases of IgA nephropathy are known to be associated with alterations in collagen type IV. In a familial IgA nephropathy pedigree, an association with the locus on chromosome 2q36, which includes COL4A3 and COL4A4, has been identified [25]. Subsequent studies have reported finding pathogenic mutations in COL4A35 in 20% of familial IgA nephropathy cases [26]. More recently, this phenomenon has also been reported in sporadic IgA nephropathy cases. Variants in COL4A35 genes were observed in 31.1% of IgA nephropathy cases with a thin GBM (<250 nm) [27]. Familial FSGS is another disorder where pathogenic variants in the same genes can be identified [28,29].

Since there are no specific light microscopy findings for AS, IgA nephropathy and FSGS could be considered as differential diagnoses of AS. On the other hand, when there is a family history or findings such as thin GBM in IgA nephropathy and FSGS, genetic testing for COL4A35 genes might also be considered.

Conclusion and summary

When examined under light microscopy, AS patients’ kidney tissue may exhibit various changes such as glomerular FSGS, mesangial hypercellularity, and interstitial foam cell collection, but these changes are not diagnostic. Electron microscopy reveals alterations in the GBM thickness and features like basket weaving and lamellation. Efforts were made to confirm AS through collagen α chains staining; however, in recent times, the prevailing trend is to use genetic testing, including NGS.

Notes

Conflicts of interest

All authors have no conflicts of interest to declare.

Data sharing statement

The data presented in this study are available from the corresponding author upon reasonable request.

Authors’ contributions

Conceptualization: KBL, BJL

Data curation: KBL

Writing–original draft: KBL

Writing–review & editing: MJ, BJL

All authors read and approved the final manuscript.

References

1. Hostikka SL, Eddy RL, Byers MG, Höyhtyä M, Shows TB, Tryggvason K. Identification of a distinct type IV collagen alpha chain with restricted kidney distribution and assignment of its gene to the locus of X chromosome-linked Alport syndrome. Proc Natl Acad Sci U S A 1990;87:1606–1610.
2. Boye E, Mollet G, Forestier L, et al. Determination of the genomic structure of the COL4A4 gene and of novel mutations causing autosomal recessive Alport syndrome. Am J Hum Genet 1998;63:1329–1340.
3. Heidet L, Arrondel C, Forestier L, et al. Structure of the human type IV collagen gene COL4A3 and mutations in autosomal Alport syndrome. J Am Soc Nephrol 2001;12:97–106.
4. Noël LH. Renal pathology and ultrastructural findings in Alport’s syndrome. Ren Fail 2000;22:751–758.
5. Quinlan C, Rheault MN. Genetic basis of type IV collagen disorders of the kidney. Clin J Am Soc Nephrol 2021;16:1101–1109.
6. Cosgrove D. Glomerular pathology in Alport syndrome: a molecular perspective. Pediatr Nephrol 2012;27:885–890.
7. Meehan DT, Delimont D, Cheung L, et al. Biomechanical strain causes maladaptive gene regulation, contributing to Alport glomerular disease. Kidney Int 2009;76:968–976.
8. Kruegel J, Rubel D, Gross O. Alport syndrome: insights from basic and clinical research. Nat Rev Nephrol 2013;9:170–178.
9. Pedrosa AL, Bitencourt L, Paranhos RM, et al. Alport syndrome: a comprehensive review on genetics, pathophysiology, histology, clinical and therapeutic perspectives. Curr Med Chem 2021;28:5602–5624.
10. Adam J, Connor TM, Wood K, et al. Genetic testing can resolve diagnostic confusion in Alport syndrome. Clin Kidney J 2014;7:197–200.
11. Wu Y, Chen Y, Chen D, Zeng C, Li L, Liu Z. Presence of foam cells in kidney interstitium is associated with progression of renal injury in patients with glomerular diseases. Nephron Clin Pract 2009;113:c155–c161.
12. Lusco MA, Fogo AB. Hereditary nephritis and thin glomerular basement membrane lesion. Glomerular Dis 2021;1:135–144.
13. Yamashita M, Lin MY, Hou J, Ren KY, Haas M. The continuing need for electron microscopy in examination of medical renal biopsies: examples in practice. Glomerular Dis 2021;1:145–159.
14. Arslansoyu Camlar S, Ünlü M, et al. Contribution of electron microscopy to the clinicopathologic diagnosis in childhood glomerular renal diseases. Fetal Pediatr Pathol 2019;38:299–306.
15. Raju P, Cimbaluk D, Korbet SM. The variable course of women with X-linked Alport Syndrome. Clin Kidney J 2013;6:630–634.
16. Imafuku A, Nozu K, Sawa N, et al. Autosomal dominant form of type IV collagen nephropathy exists among patients with hereditary nephritis difficult to diagnose clinicopathologically. Nephrology (Carlton) 2018;23:940–947.
17. Kagawa M, Kishiro Y, Naito I, et al. Epitope-defined monoclonal antibodies against type-IV collagen for diagnosis of Alport’s syndrome. Nephrol Dial Transplant 1997;12:1238–1241.
18. Savige J, Renieri A, Ars E, et al. Digenic Alport syndrome. Clin J Am Soc Nephrol 2022;17:1697–1706.
19. Savige J, Ariani F, Mari F, et al. Expert consensus guidelines for the genetic diagnosis of Alport syndrome. Pediatr Nephrol 2019;34:1175–1189.
20. Daga S, Ding J, Deltas C, et al. The 2019 and 2021 International Workshops on Alport Syndrome. Eur J Hum Genet 2022;30:507–516.
21. Savige J, Lipska-Zietkiewicz BS, Watson E, et al. Guidelines for genetic testing and management of Alport syndrome. Clin J Am Soc Nephrol 2022;17:143–154.
22. Uzzo M, Moroni G, Ponticelli C. Thin basement membrane: an underrated cause of end-stage renal disease. Nephron 2023;147:383–391.
23. Kashtan CE, Ding J, Garosi G, et al. Alport syndrome: a unified classification of genetic disorders of collagen IV α345: a position paper of the Alport Syndrome Classification Working Group. Kidney Int 2018;93:1045–1051.
24. Savige J. Heterozygous pathogenic COL4A3 and COL4A4 variants (autosomal dominant Alport syndrome) are common, and not typically associated with end-stage kidney failure, hearing loss, or ocular abnormalities. Kidney Int Rep 2022;7:1933–1938.
25. Paterson AD, Liu XQ, Wang K, et al. Genome-wide linkage scan of a large family with IgA nephropathy localizes a novel susceptibility locus to chromosome 2q36. J Am Soc Nephrol 2007;18:2408–2415.
26. Li Y, Groopman EE, D’Agati V, et al. Type IV collagen mutations in familial IgA nephropathy. Kidney Int Rep 2020;5:1075–1078.
27. Yuan X, Su Q, Wang H, et al. Genetic variants of the COL4A3, COL4A4, and COL4A5 genes contribute to thinned glomerular basement membrane lesions in sporadic IgA nephropathy patients. J Am Soc Nephrol 2023;34:132–144.
28. Malone AF, Phelan PJ, Hall G, et al. Rare hereditary COL4A3/COL4A4 variants may be mistaken for familial focal segmental glomerulosclerosis. Kidney Int 2014;86:1253–1259.
29. Gast C, Pengelly RJ, Lyon M, et al. Collagen (COL4A) mutations are the most frequent mutations underlying adult focal segmental glomerulosclerosis. Nephrol Dial Transplant 2016;31:961–970.

Article information Continued

Figure 1.

Interstitial accumulation of foam cells (arrows) is frequently observed in Alport syndrome (periodic acid-Schiff stain, ×200).

Figure 2.

Electron microscopic findings of Alport syndrome.

The glomerular basement membrane (GBM) shows alternating thin and thick segments and frequent foot process effacement (A, ×3,000). In more progressed cases, the GBM shows marked irregularity with lamellation and scalloping of the lamina densa (B, ×20,000) and intramembranous microspherules (arrowheads) (C, ×8,000).

Figure 3.

Immunofluorescent staining of collagen IV (×200).

Normal control tissue reveals both α2 chain stain (red) and α5 chain stain (green) along the glomerular basement membrane and Bowman’s capsule (A). Male X-linked Alport syndrome reveals complete loss of α5 chain (B), while female heterozygote Alport syndrome shows partial loss of α5 chain (C).