Thin glomerular basement membrane disease: clinical significance of a morphological diagnosis--a collaborative study of the Italian Renal Immunopathology Group.

BACKGROUND: Thin glomerular basement membrane disease (TBMD) is a nephropathy defined by diffuse thinning of the glomerular basement membrane (GBM) at electron microscopy examination, without the alterations of Alport's syndrome (ATS). It is known that many patients with TBMD have a type IV collagen disorder and that the disease occasionally may be progressive. This study investigated 51 patients with the morphological diagnosis of TBMD lacking any sign of ATS, with the aim of defining the prevalence of type IV collagen mutations and the course of the disease. METHODS: Patients were investigated as follows: (a) clinical picture and family investigation; (b) renal biopsy findings; (c) immunohistochemical study of renal tissue for collagen IV alpha-chains; (d) pedigree reconstruction and molecular investigations in genes encoding type IV collagen chains, when DNA samples were available; and (e) follow-up data. RESULTS: Renal biopsy analysis revealed no light microscopy changes in 27 patients and minimal abnormalities in the remainder. Global glomerular sclerosis was found in seven cases and superimposed mesangial immunoglobulin-A deposits in four. Normal staining of GBM for alpha(IV) chains was observed in all but one patient, where alpha5(IV) was absent and molecular investigation revealed a COL4A5 mutation. Five out of 25 cases had a mutation in the COL4A3/COL4A4 genes. Eight out of 38 patients followed up for 12-240 months (21%) showed signs of disease progression or hypertension. CONCLUSIONS: This study confirms that a considerable proportion of patients with TBMD have a type IV collagen disorder and that this lesion is not always benign. Thus, families should be investigated carefully whenever possible and patients and affected relatives should be examined periodically for signs of disease progression.     

COL4A4 mutation in thin basement membrane disease previously described in Alport syndrome

BACKGROUND: Carriers of autosomal-recessive and X-linked Alport syndrome often have a thinned glomerular basement membrane (GBM) and have mutations in the COL4A3/COL4A4 and COL4A5 genes respectively. Recently, we have shown that many individuals with thin basement membrane disease (TBMD) are also from families where hematuria segregates with the COL4A3/COL4A4 locus. This study describes the first COL4A4 mutation in an individual with biopsy-proven TBMD who did not have a family member with autosomal-recessive or X-linked Alport syndrome, inherited renal failure, or deafness. METHODS: The index case and all available family members were examined for dysmorphic hematuria> 50,000/mL using phase contrast microscopy and for segregation of hematuria with the COL4A3/COL4A4 and COL4A5 loci using DNA satellite markers. COL4A4 exons from the index case were then studied using the enzyme mismatch cleavage method, and exons that demonstrated abnormal cleavage products were sequenced. RESULTS: Hematuria in this family segregated with a haplotype at the COL4A3/COL4A4 locus (P = 0.031) but not with haplotypes at the COL4A5 locus. A mutation in COL4A4 that changed C to T resulting in an arginine residue being replaced by a stop codon (R1377X) was demonstrated in exon 44, which encodes part of the alpha 4(IV) collagen sequence close to the junction with the noncollagenous domain. This mutation was present in all five family members with hematuria, but not in the four unaffected family members, 33 unrelated individuals with TBMD, or 22 nonhematuric normals. CONCLUSIONS: R1377X has been described previously in a compound heterozygous form of autosomal-recessive Alport syndrome. Our observation is evidence that TBMD can represent a carrier state for autosomal-recessive Alport syndrome in at least some individuals.     

Role of the Podocyte (and Glomerular Endothelium) in Building the GBM

This article summarizes the basic cellular and extracellular events in the development of the glomerulus and assembly of the glomerular basement membrane (GBM), paying special attention to laminin (LM) and type IV collagen. Cellular receptors for GBM proteins, including the integrins, dystroglycan, and discoidin domain receptor 1 also are discussed. Evidence is reviewed showing that the laminin isoform present in the earliest GBM, LM-111, and final isoform found in the mature GBM, LM-521, are each derived from both endothelial cells and podocytes. Although the early collagen α1α2α1(IV) similarly derives from endothelial cells and podocytes, collagen α3α4α5(IV) found in fully mature GBM is a product solely of podocytes. Genetic diseases affecting laminin and type IV collagen synthesis also are presented, with an emphasis on mutations to LAMB2 (Pierson syndrome) and COL4A3, COL4A4, and COL4A5 (Alport syndrome), and their experimental mouse models. Stress is placed on the assembly of a compositionally correct GBM for the acquisition and maintenance of glomerular barrier properties.     

No linkage to the COL4A3 gene locus in Japanese thin basement membrane disease families

Summary: Patients with thin basement membrane disease (TBMD) exhibit persistent haematuria with a diffuse thinning of the glomerular basement membrane (GBM), especially of the lamina densa. It appears to be an autosomal dominant trait. It has been reported that the Goodpasture epitope, which is located in the non-collagenous domain of type IV collagen α 3 chain, may be reduced in patients with TBMD. We speculated that the candidate gene for TBMD could be the type IV collagen α 3 chain gene ( COL4A3 ), which is present closely to type IV collagen α 4 chain gene ( COL4A4 ) on chromosome 2q35–37. We conducted a linkage analysis to investigate the relationship between familial TBMD and COL4A3 gene, using COL4A3 cDNA polymorphism and a (CA)_n microsatellite marker located in the COL4A3 gene. We examined 32 individuals from four Japanese families with TBMD. There were no associations between the patients with haematuria and certain alleles of the two markers in the pedigrees of three families. It has been reported that type IV collagen α 1 chain gene ( COL4A1 ) and α 2 chain gene ( COL4A2 ) are not involved in TBMD, and that α 5 chain gene ( COL4A5 ) and a 6 chain gene ( COL4A6 ) map to chromosome X. In conclusion, our findings suggested that familial TBMD is not caused by the genetic abnormalities of type IV collagen genes isolated thus far.     

Quantitative analysis of glomerular type IV collagen alpha3-5 chain expression in children with thin basement membrane disease

Thin basement membrane disease (TBMD) and Alport syndrome, two forms of childhood nephritis, have generally been considered to be hereditary diseases. In Alport syndrome, several reports have demonstrated pathogenic mutations of the genes encoding type IV collagen alpha3, 4 and/or 5 chain [alpha3, 4 and/or 5(IV)]. Previous immunohistochemical studies indicated that these antigens were absent from the glomerular basement membrane (GBM) in Alport syndrome, whilst a normal labeling pattern was maintained in TBMD. In order to understand the role of the alpha3, 4 and/or 5(IV) antigens in TBMD, we used confocal laser scanning microscopy (CLSM) to examine cryosections of renal biopsies from 12 children with TBMD and 11 control children with IgA nephropathy (IgAN) without proteinuria. All tissue sections were stained with a mixture of FITC-conjugated rat monoclonal antibodies directed against human alpha3(IV), alpha4(IV) or alpha5(IV) and a Texas red-conjugated rat monoclonal antibody raised against human alpha2(IV). CLSM was performed and quantitative analysis of the ratio of the staining signal for alpha3(IV), alpha4(IV) or alpha5(IV) to alpha2(IV) [alpha3(IV), alpha4(IV) or alpha5(IV)/alpha2(IV)] along the GBM was determined. The average number of pixels for alpha3(IV), alpha4(IV) or alpha5(IV)/alpha2(IV) was 3.52 +/- 1.49, 3.54 +/- 1.25 and 1.09 +/- 0.49 in TBMD and 3.62 +/- 1.46, 3.99 +/- 1.53 and 1.77 +/- 0.47 in control subjects, respectively. Statistical analysis indicated that alpha5(IV)/alpha2(IV) ratio was significantly lower (p < 0.01) in children with TBMD compared to controls. These findings raise the possibility that TBMD might be caused by an abnormality of the alpha5(IV) antigen along the GBM.     

A novel model of autosomal dominant Alport syndrome in Dalmatian dogs.

BACKGROUND: Autosomal dominant Alport syndrome is a rare inherited disease characterized clinically by haematuria, renal failure and deafness, and ultrastructurally by a lamellated glomerular basement membrane (GBM). It is usually caused by mutations in the COL4A3 or COL4A4 genes which code for the alpha3 and alpha4 chains of type IV collagen. We describe here a novel spontaneous model of autosomal dominant Alport syndrome in Dalmatian dogs. METHODS: Affected dogs were identified by a urinary protein creatinine >/=0.3. A total of 10 affected adult Dalmatians and eight unaffected age- and sex-matched dogs from breeds other than Dalmatians were examined. In addition, kidneys from five Dalmatian fetuses from affected mothers were examined histologically and ultrastructurally. RESULTS: All affected dogs were purebred Dalmatians and had a common progenitor. Successive generations were affected, and males and females were affected equally often and equally severely, consistent with autosomal dominant inheritance. The median age at onset of renal failure was 18 months (range 8 months to 7 years). Affected dogs were not clinically deaf, and did not have the ocular abnormalities seen in human X-linked or autosomal recessive Alport syndrome. In addition, they did not have the leucocyte inclusions, low platelet counts or large platelets seen in autosomal dominant hereditary nephritis due to MYH9 mutations. The renal histology and ultrastructural appearance of the GBM appeared to be normal in utero. However, affected adult kidneys demonstrated segmental glomerular hyalinosis and sclerosis with tubulo-interstitial inflammation and fibrosis, and on ultrastructural examination the GBM was lamellated with subepithelial frilling, vacuolation and occasional intramembranous deposits. All alpha1(IV)-alpha5(IV) type IV collagen chains were present in the affected GBM and Bowman's capsule. CONCLUSIONS: Autosomal dominant Alport syndrome in Dalmatians resembles the disease in Bull terriers but has arisen independently. These models will enable us to determine how genetic mutations affect the corresponding proteins and overall membrane structure in autosomal dominant Alport syndrome.     

The pathogenesis of Alport syndrome involves type IV collagen molecules containing the alpha 3(IV) chain: evidence from anti-GBM nephritis after renal transplantation.

Mutations in the COL4A5 collagen gene have been implicated as the primary defect in Alport syndrome, a heritable disorder characterized by sensorineural deafness and glomerulonephritis that progresses to end-stage renal failure. In the present study, the molecular nature of the defect in Alport glomerular basement membrane (GBM) was explored using anti-GBM alloantibodies (tissue-bound and circulating) produced in three Alport patients subsequent to renal transplantation. The alloantibodies bound to the alpha 3(IV)NC1 domain of type IV collagen and not to any other basement membrane component. In tissue sections, the alloantibodies bound specifically to peripheral GBM in normal kidney and the affected renal transplant but not to that of Alport kidney. These results establish that: the alpha 3 chain in type IV collagen molecules, the Goodpasture autoantigen, is the target alloantigen in post-transplant anti-GBM nephritis in patients with Alport syndrome, and that a molecular commonality exists in the pathogenesis of anti-GBM nephritis causing loss of renal allografts in patients with Alport syndrome and renal failure in patients with Goodpasture syndrome. These findings implicate: (1) defective assembly of type IV collagen molecules containing the alpha 3(IV) chain in Alport GBM; and (2) the existence of a mechanism linking the assembly of molecules containing the alpha 3(IV) chain with those containing the alpha 5(IV) chain.     

Glomerular pathology in Alport syndrome: a molecular perspective

We have known for some time that mutations in the genes encoding 3 of the 6 type IV collagen chains are the underlying defect responsible for both X-linked (where the COL4A5 gene is involved) and autosomal (where either COL4A3 or COL4A4 genes are involved) Alport syndrome. The result of these mutations is the absence of the sub-epithelial network of all three chains in the glomerular basement membrane (GBM), resulting, at maturity, in a type IV collagen GBM network comprising only α1(IV) and α2(IV) chains. The altered GBM functions adequately in early life. Eventually, there is onset of proteinuria associated with the classic and progressive irregular thickening, thinning, and splitting of the GBM, which culminates in end-stage renal failure. We have learned much about the molecular events associated with disease onset and progression through the study of animal models for Alport syndrome, and have identified some potential therapeutic approaches that may serve to delay the onset or slow the progression of the disease. This review focuses on where we are in our understanding of the disease, where we need to go to understand the molecular triggers that set the process in motion, and what emergent therapeutic approaches show promise for ameliorating disease progression in the clinic.     

Alport syndrome or progressive hereditary nephritis with hearing loss

Alport syndrome is an inherited disorder characterized by progressive hematuric nephritis with structural defects of the glomerular basement membrane, and sensorineural deafness. Ocular abnormalities are frequently associated. The incidence is approximatively 1/5000. The renal disease is severe in male patients and should be responsible for 2% of end-stage renal failure. Alport syndrome is heterogeneous at the clinical and genetic levels. It occurs as a consequence of structural abnormalities in type IV collagen, the major constituent of basement membranes. Six genetically distinct chains of type IV collagen have been identified. Mutations in the COL4A5 gene located at Xq22, and encoding the alpha 5(IV) chain are responsible for X-linked Alport syndrome whereas COL4A3 or COL4A4 located "head to head" on chromosome 2 are involved in the rarer autosomal forms of the disease.     

Thin basement membrane nephropathy

Thin basement membrane nephropathy. Thin basement membrane nephropathy (TBMN) is the most common cause of persistent glomerular bleeding in children and adults, and occurs in at least 1% of the population. Most affected individuals have, in addition to the hematuria, minimal proteinuria, normal renal function, a uniformly thinned glomerular basement membrane (GBM) and a family history of hematuria. Their clinical course is usually benign. However, some adults with TBMN have proteinuria >500 mg/day or renal impairment. This is more likely in hospital-based series of biopsied patients than in the uninvestigated, but affected, family members. The cause of renal impairment in TBMN is usually not known, but may be due to secondary focal segmental glomerulosclerosis (FSGS) or immunoglobulin A (IgA) glomerulonephritis, to misdiagnosed IgA disease or X-linked Alport syndrome, or because of coincidental disease. About 40% families with TBMN have hematuria that segregates with the COL4A3/COL4A4 locus, and many COL4A3 and COL4A4 mutations have now been described. These genes are also affected in autosomal-recessive Alport syndrome, and at least some cases of TBMN represent the carrier state for this condition. Families with TBMN in whom hematuria does not segregate with the COL4A3/COL4A4 locus can be explained by de novo mutations, incomplete penetrance of hematuria, coincidental hematuria in family members without COL4A3 or COL4A4 mutations, and by a novel gene locus for TBMN. A renal biopsy is warranted in TBMN only if there are atypical features, or if IgA disease or X-linked Alport syndrome cannot be excluded clinically. In IgA disease, there is usually no family history of hematuria. X-linked Alport syndrome is much less common than TBMN and can often be identified in family members by its typical clinical features (including retinopathy), a lamellated GBM without the collagen alpha3(IV), alpha4(IV), and alpha5(IV) chains, and by gene linkage studies or the demonstration of a COL4A5 mutation. Technical difficulties in the demonstration and interpretation of COL4A3 and COL4A4 mutations mean that mutation detection is not used routinely in the diagnosis of TBMN.     

Inherited diseases of the glomerular basement membrane

The glomerular basement membrane (GBM) is a specialized form of basement membrane that has a major role in the maintenance of the glomerular filtration barrier. Like all basement membranes, it contains four main components: type IV collagen, laminin, nidogen, and heparan sulfate proteoglycans. Different isoforms of these large molecules are produced. These isoforms have a tissue-specific distribution; in the mature GBM, the major type IV collagen molecule is the alpha 3 alpha 4 alpha 5(IV) isoform, associated with laminin-521 (alpha 5 beta2 gamma 1), nidogen and agrin heparan sulfate proteoglycans. The importance of the GBM has been demonstrated by identification of hereditary glomerular diseases linked to structural anomalies of its components; for example, type IV collagen in Alport syndrome and familial benign hematuria, and laminin in Pierson syndrome. Type III collagen, an interstitial collagen, accumulates within the GBM of patients with the nail-patella syndrome, and abnormal deposition of fibronectin, another extracellular matrix protein, is characteristic of so-called fibronectin nephropathy. Development of animal models of these diseases has facilitated precise analysis of pathogenic mechanisms, but no specific treatments are available. Therapeutic trials in Alport syndrome nephropathy are underway, following promising preliminary results obtained in rodent and canine models of the disorder.     

A large tandem duplication within the COL4A5 gene is responsible for the high prevalence of Alport syndrome in French Polynesia

A large tandem duplication within the COL4A5 gene is responsible for the high prevalence of Alport syndrome in French Polynesia. Background. The prevalence of X-linked Alport syndrome, a progressive inherited nephropathy associated with mutations in the type IV collagen gene COL4A5, is remarkably high in French Polynesia. Methods. A vast clinical, genealogic, and molecular study was undertaken in Polynesia, based on public records, patients' interviews, linkage analysis, and mutation screening. Results and Conclusions. We show that the high frequency of Alport syndrome in this region is due to a founder mutation that occurred onto a common haplotype shared by affected and unaffected individuals, the presence of which precludes indirect molecular diagnosis. We have characterized the mutation as a tandem duplication of 35 COL4A5 exons, resulting in a approximately 65% increase in the length of the collagenous domain of the alpha 5(IV) chain, which is still able to assemble into type IV collagen network as shown by immunofluorescence analysis. That mutation is associated with severe and highly penetrant ocular symptoms and with uniformly thin glomerular basement membrane (GBM) in male adult patients. However, the rate of progression of the renal disease is very variable from one male patient to another, demonstrating the importance of strong modifier factors. Our results suggest that the 20% to 50% of "missing"COL4A5 mutations in X-linked Alport syndrome may be rearrangements similar to that reported here, which was not detectable by sequencing of either individual COL4A5 exons or overlapping cDNA fragments. Finally, we provide the basis for a polymerase chain reaction (PCR) assay that accurately identifies female carriers and allows adequate genetic counseling in this population.     

Choosing a mouse model to study the molecular pathobiology of Alport glomerulonephritis

Alport syndrome, caused by mutations that interfere with the normal assembly of the alpha3alpha4alpha5(IV) collagen network in the glomerular basement membrane (GBM), is the most common inherited glomerular disease leading to renal failure. A detailed knowledge of the underlying pathogenic mechanisms is necessary for developing new, more specific, and effective therapeutic strategies aimed at delaying the onset and slowing disease progression. Studies of several dog and mouse models of Alport syndrome have significantly enhanced our understanding of the disease mechanisms and provided systems for testing potential therapies. In the most widely used Col4a3-/- mouse models of autosomal-recessive Alport syndrome (ARAS), the genetic background strongly affects renal survival. One contributing factor may be the strong ectopic deposition of alpha5alpha6(IV) collagen in the GBM of Col4a3-/- mice on the C57BL/6J background, which is almost undetectable on the 129/Sv background. This isoform 'switch' has not been observed in human ARAS, although it had been reported in the dog model of ARAS. In human patients as well as dog and mouse models of X-linked Alport syndrome, the alpha3-alpha6(IV) collagen chains are absent from the GBM. These biochemical differences among Alport animal models provide an opportunity to determine how the molecular makeup of the GBM affects the glomerular function. At the same time, potentially confounding influences of characteristics unique to a particular strain or model should be carefully considered in the design of studies aiming to define key events underlying the pathobiology of Alport glomerular disease.     

Glomerular changes in microscopic haematuria, studied by quantitative immunoelectron microscopy and in situ zymography.

BACKGROUND:Haematuria of glomerular origin, even if mild, implies the development of defects in the glomerular basement membrane (GBM). In diseases where there is no infiltration of leukocytes into the glomerulus-such as thin basement membrane disease (TBMD) and histologically mild cases of IgA nephropathy (IgAN)-the mechanism by which such defects form is unclear. METHODS:Frozen renal tissue from 18 cases of TBMD, 18 of mild IgAN and 18 cases with no detectable abnormality were studied: (i) by quantitative in situ zymography, to estimate the activity of glomerular collagenases; and (ii) by quantitative immunoelectron microscopy to estimate the amount of major basement membrane proteins per unit length and per unit area of glomerular basement membrane. RESULTS:Cases of IgAN showed considerably more glomerular collagenase activity than normal (P=0.001). Thin basement membrane disease showed no difference in collagenase activity. A count of LCA-positive cells in glomeruli confirmed that the IgAN cases did not show glomerular leukocyte infiltration. Conversely, cases of IgAN showed no difference in GBM composition from normal, nor was any difference in GBM thickness detected in this group. However, cases of TBMD showed considerably less laminin (P=0.0008), fibronectin (P=0.002) and type VI collagen (P=0.0005) per unit length of basement membrane. Collagen IV showed a smaller reduction per unit length (P=0.01), but unlike the other protein studies it appeared to be present in higher concentration per unit area (P=0.03), suggesting that it is more 'compact' in TBMD disease. CONCLUSIONS:Two distinct mechanisms of haematuria seem to be involved in these two conditions. In IgAN there is increased activity of enzymes that can degrade GBM, probably reflecting mesangial cell activation. In TBMD an abnormal composition of the thinned GBM is confirmed. When considered with published reports of genetic abnormalities in TBMD, these results raise the possibility of an abnormal interaction between collagen IV and laminin.     

Segregation of hematuria in thin basement membrane disease with haplotypes at the loci for Alport syndrome

BACKGROUND: Inherited hematuria is common and is usually attributed to thin basement membrane disease (TBMD). The aim of this study was to determine how often hematuria in families with TBMD segregated with haplotypes at the chromosomal loci for autosomal recessive and X-linked Alport syndrome (COL4A3/COL4A4 and COL4A5, respectively). METHODS: The families of 22 individuals with TBMD on renal biopsy and with urinary glomerular red blood cell (RBC) counts of more than 50,000/mL were studied using phase-contrast microscopy of the urine and DNA microsatellite markers. Eighteen families had at least two members with hematuria. RESULTS: Hematuria segregated with or was consistent with segregation at the COL4A3/COL4A4 locus in eight (36%) families (P < 0.05 in 5 of these) and at the COL4A5 locus in four (18%) families (P < 0.05 in 2). The lack of segregation in the other 10 (45%) families may have occurred because of incomplete penetrance of the hematuria, de novo mutations, coincidental hematuria in other family members, or the presence of a novel gene locus. In four different families, three of which had hematuria that segregated with the COL4A3/COL4A4 locus, four family members with the hematuria haplotype had spouses with coincidental hematuria (4 of 29, 14%). However, none of their four offspring who had also inherited the hematuria haplotype had the clinical features of autosomal recessive Alport syndrome. CONCLUSIONS: Hematuria in families with TBMD commonly segregates with the COL4A3/COL4A4 locus and thus results from mutations in the same genes as autosomal recessive Alport syndrome. Sometimes TBMD may be confused with the carrier state for X-linked Alport syndrome. However, nearly half of the families in this study had hematuria that did not segregate with the loci for either autosomal recessive or X-linked Alport syndrome.     

Laminin-1 reexpression in Alport mouse glomerular basement membranes

BACKGROUND: Alport disease is a heritable basement membrane disorder caused by mutations in genes encoding the alpha3, alpha4, or alpha5 chains of type IV collagen, which normally comprise the collagenous network of mature glomerular basement membranes (GBMs). In Alport disease, the alpha3(IV), alpha4(IV), alpha5(IV) collagen network is absent and substituted for by alpha1(IV), and alpha2(IV) collagen, which normally is present only in developing, immature GBMs. The disease is marked by progressive GBM thickening and delamination, proteinuria, and renal failure. In addition to collagen IV dysregulation, abnormal GBM laminins also occur and may contribute to the pathogenesis of Alport glomerulopathy. METHODS: To investigate laminin dysregulation in a mouse model of Alport disease, we used antibodies specific for laminin-alpha1 and -beta1 chains (to recognize laminin-1), and -alpha5 chain (to recognize laminin-11), and evaluated their distribution during glomerular development in alpha3(IV) collagen-deficient mice. RESULTS: Developing glomeruli of infant alpha3(IV) collagen knockout mice underwent normal down-regulation of laminin-1, but laminin-1 chains were then reexpressed in maturing glomeruli, becoming concentrated in the subepithelial GBM projections typical of Alport disease. Immunoelectron microscopy showed that laminin-1 reexpression took place in both glomerular endothelial cells and podocytes. CONCLUSIONS: The absence of a alpha3(IV), alpha4(IV), alpha5(IV) network may stimulate reexpression of laminin-1 by Alport mouse endothelial cells and podocytes. This abnormal GBM, which is more characteristic of immature glomeruli, may promote podocyte foot process effacement and reversion to a less differentiated state.     

Alport-like glomerular basement membrane changes with renal-coloboma syndrome

BACKGROUND: Autosomal dominant mutations in paired box gene 2 (PAX2), on chromosome 10q24, are responsible for renal coloboma syndrome (RCS). The role of PAX2 in glomerular basement membrane (GBM) formation and maintenance remains unknown. CASE-DIAGNOSIS: We report a case of a 13-year-old Japanese girl who had both optic disk coloboma and renal insufficiency. Her father and sister also had both coloboma and renal dysfunction. Renal pathological findings revealed a basket-weave pattern of the GBM, which was compatible with Alport syndrome, but type IV collagen α5 staining was normal. The patient's findings of coloboma and renal dysfunction suggested that she had RCS, and genetic analysis revealed a PAX2 heterozygous mutation in exon 2 (c.76dup, p.Val26Glyfsx27) without any mutations of COL4A3, COL4A4, and COL4A5, which are responsible for autosomal and X-linked Alport syndrome. CONCLUSIONS: PAX2 mutations may result in abnormal GBM structure.     

Quantitative immunoelectron-microscopic analysis of the type IV collagen alpha1-6 chains in the glomerular basement membrane in childhood thin basement membrane disease

AIM: Thin basement membrane disease (TBMD) is characterized histologically by diffuse thinning of glomerular basement membrane (GBM). Although recent genetic analysis has shown that TBMD might be included within type IV collagen disorders, conventional immunohistochemical studies demonstrated normal labeling of type IV collagen alpha chains in the GBM. We have, however, successfully used confocal laser scanning microscopy to demonstrate a significantly reduced signal of type IV collagen alpha5 chain (alpha5(IV)) along capillary walls in TBMD. In order to further understand the association of type IV collagen with TBMD, we used immunoelectron microscopy to examine renal biopsies from 6 children with TBMD and six control children with minimal change nephrotic syndrome. METHODS: Ultrathin sections of LR gold resin were incubated with a rat monoclonal antibody against human alpha1(IV), alpha2(IV), alpha3(IV), alpha4(IV) alpha5(IV) or alpha6(IV) followed by colloidal gold conjugated goat anti-rat IgG. After taking electron micrographs, the labeling was quantitatively evaluated in the area occupied by the segments of basement membrane. The basement membrane was divided into three equal segments viz. subepithelial side, central portion and subendothelial side. RESULTS: In control subjects, the number of gold particles for alpha1(IV) or alpha2(IV) was significantly greater in the subendothelial side and central portion than in the subepithelial side of the GBM, whilst alpha3(IV), alpha4(IV) or alpha5(IV) labeling was significantly more prominent in the central portion compared to the subepithelial and subendothelial side of the GBM. TBMD samples showed a similar distribution pattern except that the subepithelial side and central portion of the GBM had a significantly reduced amount of alpha5(IV) antigen compared to control subjects. CONCLUSION: This is the first report demonstrating a diminished labeling intensity of alpha5(IV) in the central portion and subepithelial side of the GBM in renal biopsy specimens from patients with TBMD. These findings suggest that an abnormality of alpha5(IV) might possibly be associated with the pathogenesis of TBMD.     

Distribution of the alpha 1 and alpha 2 chains of collagen IV and of collagens V and VI in Alport syndrome.

We compared the distribution of the alpha 1 and alpha 2 chains of collagen IV and of collagens V and VI in glomeruli of males with Alport syndrome to their distribution in normal glomeruli and glomeruli from patients with non-Alport renal diseases. alpha 1(IV), alpha 2(IV), collagen V and collagen VI are normally restricted to the mesangium and the subendothelial aspect of the glomerular basement membrane (GBM). In contrast, these proteins were present throughout the entire width of the GBM in Alport glomeruli. These alterations were apparent in "early" Alport glomeruli, that is, those exhibiting minimal abnormalities by light microscopy, and they were further accentuated in sclerosing Alport glomeruli. Obsolescent Alport glomeruli, in which the capillary tuft had collapsed and few remaining cell nuclei were present, exhibited nearly complete loss of alpha 1(IV) and alpha 2(IV), like obsolescent glomeruli in non-Alport diseased kidneys. However, the matrix of obsolescent Alport glomeruli stained intensely for collagen V and collagen VI, while these collagen types were not prominent in obsolescent glomeruli of non-Alport diseases kidneys. These observations suggest that the process of glomerulosclerosis in Alport kidneys has attributes unique to this disease. It would also appear that mutations affecting the Alport gene product have secondary effects on the distribution of other GBM constituents.