key: cord-0717132-84f5zxxk authors: Xiao, Andrew Y.; Kanaan, Hassan D.; Lai, Zongshan; Li, Wei; Zhang, Ping L. title: Role of progenitor cell marker CD133 in supporting diagnosis of collapsing glomerulopathy date: 2022-01-03 journal: Int Urol Nephrol DOI: 10.1007/s11255-021-03078-0 sha: f37e204932d3ee3fb3a93d53398d46f64f0bb9fa doc_id: 717132 cord_uid: 84f5zxxk PURPOSE: A previous immunofluorescent study suggests that, in collapsing glomerulopathy, most hyperplastic podocytes that stained positively for a progenitor cell marker CD133 are derived from CD133 + parietal epithelial cells. In pathology practice, not all renal biopsies with collapsing glomerulopathy show the typical morphologic features for this entity, which include florid podocyte hyperplasia, collapsing glomerular capillary loops, and cystic tubular dilation. This study was made to determine if CD133 staining using an immunohistochemical method can be used to confirm hyperplastic podocytes and identify extensive acute tubular injury in collapsing glomerulopathy. METHODS: Twenty-one collapsing glomerulopathy biopsies were stained for CD133 and compared with 15 biopsies with focal segmental glomerulosclerosis, not otherwise specified (FSGS). RESULTS: All patients with collapsing glomerulopathy were of African American descent with prominent renal failure and nephrotic range proteinuria. In contrast, the FSGS group consisted of patients from a variety of ethnic backgrounds with nephrotic range proteinuria but relatively low serum creatinine. The striking finding was that all collapsing glomerulopathy cases showed positive CD133 staining in the clusters of hyperplastic podocytes. There was significantly higher CD133-positive staining rate for hyperplastic podocytes (38%) in the glomeruli of the collapsing glomerulopathy group when compared to small clusters of hyperplastic podocytes in the FSGS group (8%). In addition, when compared to the relatively weak CD133 staining in the proximal tubules of the FSGS group, the proximal tubules of the collapsing glomerulopathy group all showed diffuse and strong CD133 staining as a feature of severe acute tubular injury, which corresponded to the high serum creatinine levels in these patients. CONCLUSION: Our data indicate that the combination of the distinctive mosaic CD133 staining in hyperplastic podocytes and the diffuse tubular CD133 staining is helpful in supporting a diagnosis of collapsing glomerulopathy. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s11255-021-03078-0. CD133, also known as prominin-1, is a membranous glycoprotein encoded by the PROM1 gene in human, but its specific functions remain unclear [1, 2] . CD133 has been investigated for its potential utility as a stem cell marker in different adult organs and tumors [2] . The activation of CD133 in the stem cells of the kidney may be related to the activation of hypoxia induced factors (HIFs) and their master mechanism for oxygen sensing and gene regulations [3, 4] . The parietal epithelium along the Bowman's capsule stains positively for the progenitor markers CD133 and CD24 and are thus identified as multipotent progenitor cells [5] [6] [7] . The parietal epithelium continuously differentiates into the visceral epithelium (podocytes) of glomeruli, which are terminally differentiated and thus stain negatively for CD133. Some tracing studies also support the view that podocytes are derived from the parietal epithelium [8, 9] . In addition, the CD133-positive progenitor cells are also scattered along proximal tubules under normal circumstances [10] [11] [12] . The injection of CD133 progenitor cells into variants of rodent models with acute renal failure and/or proteinuria can significantly improve the renal function and reduce proteinuria, implying the regenerative capacity of the renal progenitor cells [6, 7] . Diagnosis of collapsing glomerulopathy can be challenging if the typical features, such as florid podocyte hyperplasia and obvious cystic dilation in renal tubules, are absent. Collapsing glomerulopathy (also known as collapsing variant of focal segmental glomerulosclerosis) can result from multiple etiologies, including HIV infection and genetic abnormalities such as APOL1 mutations in African American patients [13, 14] . Recently, there are scattered reports of collapsing glomerulopathy in African American patients that contracted COVID-19 infection, but whether the collapsing glomerulopathy is directly related to the viral infection remains debatable [15] [16] [17] . Regarding the origin of the hyperplastic podocytes in the collapsing glomerulopathy, one key study using immunofluorescent techniques indicates that cellular crescents in crescentic glomerulonephritis and hyperplastic podocytes in collapsing glomerulopathy all come from the same parietal epithelium of the glomeruli [18] . The study also finds that there are 3 populations of hyperplastic podocytes in the collapsing glomerulopathy. Using confocal microscopy to evaluate several merged marker expressions, the study determined that there are approximately 60% immature podocytes (CD133 + , CD24 + , podocalyxin − [PDX, a podocyte marker] nestin − [another podocyte marker]), 30% mature podocytes (CD133 − , CD24 − , PDX + , nestin + ), and 10% transitional podocytes (CD133 + , CD24 + , PDX + , nestin + ) [18] . The finding indicates that glomerular hyperplastic lesions are derived from the proliferation of renal progenitors at different stages of their differentiation toward mature podocytes [18] . In this study, we first investigated whether immunohistochemical staining for CD133 can be practically used to confirm the majority of hyperplastic podocytes [18] for supporting a diagnosis of collapsing glomerulopathy. Secondly, we hypothesized that the immuno-staining for CD133 can be used to highlight the extensive acute tubular injury of collapsing glomerulopathy. We found that CD133 staining identified a mosaic pattern of hyperplastic podocytes intermingled with collapsed glomerular loops and was also diffusely positive in the injured proximal tubules. These dual CD133 staining features are helpful in supporting a diagnosis of collapsing glomerulopathy. The retrospective human investigation protocol was approved by the Institutional Research Board of Beaumont Health, Michigan. In our study, there were 3 groups of renal cases. The first group consisted of negative controls (group 1, n = 12) that were taken from a de-identified archive of normal renal parenchyma (either biopsies or nephrectomy specimens for renal tumors). Biopsies with primary FSGS in the second group and collapsing glomerulopathy in the third group were used for comparison as, in adults, both FSGS and collapsing glomerulopathy represent a spectrum of podocytopathies [19] . The second group was composed of 15 renal biopsies with FSGS. Our primary FSGS biopsies were pathologically characterized with at least one glomerulus with focal segmental sclerosis by light microscopy, negative immunofluorescent studies, and diffuse fusion of foot processes in electron microscopy. In the third group, we identified 21 cases of collapsing glomerulopathy with available tissue blocks over the past 10 years. The collapsing glomerulopathy biopsies were pathologically defined with at least one glomerulus showing collapsed loops, hyperpleastic podocytes, mild to severe cystic dilation of renal tubules, negative immunofluorescent studies, and diffuse fusion of foot processes by electron microscopy. Relevant clinical information for each patient was recorded through chart reviews, which included age, gender, ethnic background, serum creatinine (sCr) levels, and protein/creatinine ratio before renal biopsies. Human kidney biopsy cores were fixed in formalin-and paraffin-embedded. Four-micron sections were dried for 60 min at 60 °C. Slides were then de-waxed in 3 xylene baths for 3 min each, 100% alcohol baths for 3 min each, and then followed by 30 s of running water. Antigen retrieval was carried out in a Tris-EDTA Buffer at pH 8.0 for 20 min at 99 °C, followed by a 20-min cool down at room temperature, and then a quick water rinse. Slides were then placed in 3% H 2 O 2 for 15 min followed by a quick water rinse and then placed in Tris buffer at pH 7.6. Slides were then stained in a programmed Dako Autostainer (DakoCytomation, Carpinteria, CA) using a Thermo Scientific UltraVision LP Detection System (Kalamazoo, MI). The program consisted of 5 min of Ultra V block, 30 min of incubation with a mouse monoclonal CD133 antibody (13A4 clone at a dilution of 1:100; from ThermoFisher, Waltham, MA), with 8 min of Primary Antibody Enhancer, 10 min of HRP polymer (equivalent to secondary antibody), and 5 min of the chromagen DAB to achieve a brown CD133 stain. Ki-67 antibodoy (MIB-1 clone, concentrate 1:100 prekit) and WT-1 antibody (clone 6F-H2, predilute) were purchased from DakoCytomation (Carpinteria, CA) and Cell Marque Cooperation (Rochlin, CA), respectively. Their immune stains followed similar procedures as CD133. De-paraffined sections were stained for PAS using Dako Artisan PAS Staining Kit (DakoCytomation, Carpinteria, CA). The steps included 12 min in periodic acid solution, two washes, 12 min of Schiff's reagent, 5 washes, 12 min in Meyers's hematoxylin solution, 5 washes, and 12 min in blurring agent before applying a cover slip. On top of CD133 stained sections, a dual-PAS staining was achieved by following the above PAS staining procedures, to highlight glomerular basement membranes and the brush borders in proximal tubules. CD133 staining intensity scores in glomeruli and proximal tubules were graded from 0 to 3 + (0, no staining; 1 + , weak fine granular staining along the complete luminal surface; 2 + , moderate granular staining; and 3 + , strong large granular staining). The percent distribution of CD133 expression in proximal tubules was also recorded. Using a H-score method, the combined scores of positive CD133 in glomeruli and the combined scores of CD133 expression in proximal tubules were calculated by CD133 staining intensity multiplying CD133 + % in glomeruli and CD133 intensity multiplying CD133 + % distribution along the proximal tubules, respectively. Results were expressed as the mean ± standard error of the mean (SEM). Data of three groups were compared using one-way analysis of variants (ANOVA) and an unpaired Student's t test was used for comparing the two groups (Stat-View program) ( Table 1) . A receiver operating characteristic (ROC) curve was generated using SAS 9.4 (Cary, NC, USA) to compare sensitivity and specificity across a range of sCr levels for the ability of sCr values to predict CD133 score. A p value of less than 0.05 is considered statistically significant. The mean age for the negative controls was approximately 9 years older than the mean age for the FSGS group, although no statistical significance was reached between the two groups ( Table 1 ). The mean age of the collapsing glomerulopathy group was more than 13 years younger than the FSGS group and the age difference was statistically significant. Furthermore, the mean age of the negative controls was significantly older than the mean value of the collapsing glomerulopathy group (p = 0.0004). All three groups were composed of a mix of female and male patients. The race data for the negative controls were not available as they were de-identified cases. Patients with FSGS consisted of 3 African Americans, 11 Caucasians, and 1 Latino American, whereas patients with collapsing glomerulopathy were all of African American decent. In the collapsing glomerulopathy group, 5 patients (5/21, 19%) had a viral infectious etiology (4 were infected by human immunodeficiency virus [HIV] and 1 had coronavirus disease 19 [COVID-19]) ( Table 2) , whereas the remaining patients did not have a medical history of infection (17/21, 81%) . No viral inclusions were identified in either HIV or COVID-19 biopsies by electron microscopy. Table 1 Clinical and pathology analysis in negative controls, FSGS, and collapsing glomerulopathy Data of three groups, including age, serum creatinine levels, CD133 expression in proximal tubules and glomeruli, were compared using one-way analysis of variants (ANOVA) and an unpaired Student's t test was used for two group comparison, as for protein/creatinine ratio The levels of sCr in negative controls (mean: 0.95 mg/dl) and FSGS group (mean: 1.57 mg/dl) were significantly lower than that of collapsing glomerulopathy group (mean: 5.15 mg/dl) ( Table 1) . Proteinuria data were not available for the negative controls as their kidneys were sampled for renal tumors. Mean protein/creatinine ratio in the FSGS group (mean: 6.46) reached nephrotic range proteinuria, but was still significantly lower than that in the collapsing glomerulopathy group (mean: 10.73). Individual data from FSGS and collapsing glomerulopathy cases were listed in Table 2 . Negative controls revealed positive CD133 staining in parietal epithelial cells without staining in the podocytes (Fig. 1A) . Most FSGS biopsies also only showed positive CD133 in parietal epithelium (Fig. 1B) . Occasionally, small clusters of hyperplastic podocytes were highlighted by CD133 staining; this observation was noted in 7 out of 15 FSGS cases (Fig. 1C) . The striking finding was that all collapsing glomerulopathy biopsies showed positive staining in the clusters of proliferative podocytes (ranging from 14 to 81% of glomeruli), which displayed a mosaic pattern intermingled with collapsed glomerular capillary loops ( Fig. 1 D-F) . On dual CD133 and PAS-stained sections, negative control revealed normal glomerular capillary loops that stained positively for PAS (pinkish PAS staining), while CD133 staining (brownish) was positive in the parietal epithelial cells along the Bowman's capsule but not in the podocytes ( Fig. 2A) . Small hyperplastic podocytes were positive for CD133 in a few of the FSGS cases (Fig. 2B ). In contrast, CD133 staining highlighted the florid podocyte hyperplasia surrounding the collapsed PAS-positive glomerular capillary loops of the collapsing glomerulopathy biopsies (Fig. 2 C, D) . It was noted that CD133-positive hyperplastic podocytes were located outside of PAS-stained glomerular basement membranes while endocapillary endothelial cells and mesangial cells stained negatively for CD133 and were located within PAS-stained glomerular basement membranes. Electron microscopy revealed diffuse fusion of foot processes in both the primary FSGS group and the collapsing glomerulopathy group, confirming the nature of FSGS and collapsing glomerulopathy. Statistically, the percent of glomeruli with CD133-positive hyperplastic podocytes in the collapsing glomerulopathy group (mean: 34.90%) was significantly more than that in the FSGS group (mean: 8.98%) ( Table 1 ). The combined score of positive CD133 in glomeruli in the collapsing glomerulopathy group (mean: 93.31) was also significantly higher than that in the FSGS group (mean: 15.43). The CD133-positive hyperplastic podocytes from both FSGS and collapsing glomerulopathy groups were significantly associated with the proteinuria levels (r-value = 0.359; p-value = 0.0316). To confirm proliferative and undifferentiated nature of hyperplastic podocytes in collapsing glomerulopathy, proliferative marker Ki-67 and podocyte marker WT-1 were stained in negative control and collapsing glomerulopathy cases. Negative control glomeruli demonstrated no hyperplastic podocytes on routine hematoxylin/eosin-stained section, negative staining for CD133 in podocytes, and negative staining for Ki-67, but positive nuclear staining for WT1 in terminally differentiated podocytes (Fig. 3A-D) . In The negative controls revealed 1 or 2 CD133-positive progenitor cells per cross section of proximal tubules, which stained negatively for PAS, indicating that CD133-positive progenitor cells did not have reabsorption capacity (Fig. 4A) . It was also interesting to see that the CD133-positive cells were actually located at the tip of the less curevature of the turning segements of the proximal tubules; the turning location was highlighted by PAS-positive tubular basement membranes with invaginations ( Fig. 4A) . At the early stage of acute tubular injury, there were side-by-side and groups of two or three CD133-positive cells along proximal tubules, which were also negative for PAS staining (Fig. 4B ). With various renal injury, there was a range of positive CD133 staining from 20 to 100% in proximal tubules, whereas PAS-positive brush borders were reduced proportionally in CD133-positive segments ( Fig. 5B-D) . For biopsies with collapsing glomerulopathy, the CD133 expression in the proximal tubules was strong (3 +) and diffuse, ranging from 60 to 100% (Fig. 5D) . Furthermore, CD133 was found to be specific and sensitive in detecting acute tubular injury in correlation with serum creatinine, by showing an ROC area under the curve (AUC) value of 0.93 (very good category) (Fig. 6) . CD133 combined scores of proximal tubules were significantly higher in the collapsing glomerulopathy group (mean: 252.38) when compared to the other two groups (mean: 0.83 in controls vs 56.67 in FSGS) ( Table 1) . Our data indicate that CD133-positive hyperplastic podocytes, located outside of PAS-positive glomerular basement membranes, were unique features in supporting the diagnosis of collapsing glomerulopathy. It should be noted that a few FSGS cases showed occasional CD133-positive podocytes as well. This indicates that there may be a small overlap between FSGS and collapsing glomerulopathy. Therefore, the activation of new podocyte production from the parietal epithelium can occur in any podocytopathy, although the proliferative activity of hyperplastic podocytes becomes more obvious in the cases of collapsing glomerulopathy. Smeets et al. have characterized this type of hyperplastic podocytes into 60% of immature podocytes (CD133 + , CD24 + , PDX − , nestin − ), 30% of mature podocytes (CD133 − , CD24 − , PDX + , nestin + ) and 10% of transitional podocytes (CD133 + , CD24 + , PDX − , nestin − ) [18] . The current study showed that some of hyperplastic podocytes were positive for a proliferative marker Ki-67, but negative for another podocyte marker WT-1 as shown previously [20] , consistent with some proliferative but immature hyperplastic podocytes in the collapsing glomerulopathy [18, 20] . The overall finding indicates that glomerular hyperplastic lesions are derived from the proliferation of parietal renal progenitors at different stages of their differentiation toward mature podocytes [18] . Smeets et al. also indicate that cellular crescents in crescentic glomerulonephritis and proliferative podocytes in collapsing glomerulopathy all come from the same parietal epithelium of the glomeruli [18] . Indeed, based on our stains from a previous study [11] and the current investigation, the biomarkers CD133, proliferative marker Ki-67 and WT-1 showed similar expressions in both cellular crescents and hyperplasic podocytes (Supplement Table 1 ), but both entities have different morphologic appearances and occur in different clinical scenarios. The cellular crescents are composed of more spindle-shaped epithelial cells, directly derived from random areas of the parietal epithelial cells along the Bowman's capsule and attached to the Bowman's capsule. Their aggregated crescentic cells can physically cause the collapse of glomerular capillary loops (Supplementary Fig. 1 , the top half of schematic drawing). In contrast, the hyperplastic podocytes appear to follow the differentiation pathway from parietal epithelial cells to podocytes, look more cuboidal and are distributed along glomerular Fig. 1 , the bottom half of schematic drawing). Clinically, cellular crescents occur mainly in primary crescent glomerulonephritis associated with either ANCA or anti-glomerular basement antibodies and these patients often present with acute renal failure and nephritic symptoms, hematuria and some proteinuria. In contrast, the hyperplastic podocytes are seen in the collapsing glomerulopathy and these patients often present with renal failure and severely nephrotic range of proteinuria. From an embryology point of view, both parietal and visceral epithelial cells are derived from the cap mesenchyme in metanephors and form a double-layered network covering the glomerular capillary loops [21, 22] . Both podocytes and glomerular endothelium contribute to the building of glomerular basement membranes [23] [24] [25] . The podocytes interact with glomerular basement membranes through their foot processes and cellular cross-communication, which may play a key role in tethering and keeping the glomerular capillary loops open [26, 27] . During the development of collapsing glomerulopathy, the residual differentiated podocytes were reduced and partially replaced by clusters of immature hyperplastic podocytes in Bowman's space [28] . This may significantly reduce the role of podocytes in stretching the glomerular loops outward and hence reduce the crosscommunication and support to the glomerular endothelium. These factors would hence result in the collapse of glomerular capillary loops [25] (Supplementary Fig. 1 , the bottom half of schematic drawing). In other words, the CD133-positive hyperplastic podocytes are immature podocytes that cannot carry out the normal function that only terminally differentiated (CD133-negative) podocytes can. Common etiologies of collapsing glomerulopathy are HIV infection and mutation of APOL1 alleles in individuals of African American descent, but other infections and drug reactions can cause the disease as well [20, [29] [30] [31] . Since the beginning of 2020, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infected millions of people and caused many deaths worldwide. SARS-CoV-2 is known to cause coronavirus disease 19 (COVID-19) characterized by severe lung infection with subsequent infection of other organs through viral interaction with cell surface receptors (angiotensin-converting enzyme 2) [32] [33] [34] . Scattered studies using immunofluorescent staining and electron microscopy have reported direct renal infection in patients with COVID-19, causing acute tubular injury and collapsing glomerulopathy [15, 35, 36] . But several recent studies using RNA in-situ hybridization and electron microscopy report no definite SARS-CoV-2 detected in the renal biopsies or autopsy kidneys from COVID-19-positive patients [16, 17, 37, 38] . All of our glomerulopathy patients with collapsing glomerulopathy were of African American descent. Although our study did not conduct genetic studies for the African American patients with collapsing glomerulopathy, previous studies have demonstrated that nearly all patients with collapsing glomerulopathy are from African descent and posses genetic vulnerability for APOL1 mutation, regardless of viral infection status [16, 29, 39] . Our second finding is that the CD133-positive progenitor cells were scattered along the proximal tubules, mostly seated at the tip of the lesser curvature of the turning proximal tubules (CD133 staining in Fig. 4A and a schematic illustration in Fig. 7A) , similar to what has been reported by Lindgren et al. in 2011 [10] . They have also documented that the CD133 + tubular progenitor cells are co-localized with several biomarkers including vimentin, cytokeratin-7, and bcl-2 [10] . In this study, we found that CD133 + tubular progenitor cells stained negatively for PAS, indicating that they did not have the brush borders, thus most likely lacking of a reabsorption capacity. Taken together with the co-localization stains done by Lindgren et al. [10] , the overall findings suggest that the CD133 + tubular progenitor cells may represent a second population of cells along the proximal tubular epithelium. It is well known that HIFs are the master transcription factors regulating hypoxia-associated transcription response [40, 41] . With normal oxygen, HIF-1α is degraded. In contrast, hypoxia results in a retention of HIF-1α that subsequently activates many genes, such as erythropoietin and CD133, to deal with the hypoxic challenge [3, 4, 40] . Therefore, we raise a possibility that the CD133 + progenitor cells along proximal tubules act either as "watch dogs" or "oxygen sensing receptor cells" and may represent a part of the HIF-associated hypoxic sensing and signaling mechanism. With early tubular injury, we identified that there were clusters of CD133-positive tubular cells in the absence of PAS staining. This implies that CD133-positive tubular progenitor cells, as potential "oxygen sensing receptor cells", may spread their injury signals to the surrounding epithelial cells first before they could spread their injury signals to the rest of the tubular epithelium. Over a range of acute tubular injury, the staining for CD133 has provided us with a sensitive and specific tool to detect the acute tubular injury along proximal tubules based on the ROC curve presented. The mechanism of repairing proximal tubular injury has been debatable. In recent years, the theories for tubular repair mainly include two possibilities. The first theory is that the surviving tubular epithelial cells would repair the injured tubular epithelium [42] . The second theory would be that intraepithelial CD133-positive stem/progenitor cells can perform the repair [10] [11] [12] . Although both theories can play their roles in different stages of acute tubular injury, our observations indicate that stem/progenitor cells can repair tubular injury at least during the early stages of proximal tubular injury. CD133 can also be used to identify acute tubular injury of proximal tubules in any renal biopsies such as some FSGS cases in the primary FSGS group. However, the diffuse and strong expression of CD133 was the other unique feature in biopsies with collapsing glomerulopathy and correlated with severe acute renal failure in the vast majority of this renal disease. Both groups of FSGS and collapsing glomerulopathy had high levels of proteinuria but much less acute tubular injury was seen in FSGS group. Therefore, the severe acute tubular injury in the collapsing glomerulopathy group most likely resulted from collapsing loops associated ischemic insults to the proximal tubules rather than proteinuria alone. In summary, a normal nephron has CD133-positive parietal epithelial cells and scattered CD133-positive progenitor cells along the proximal tubules (Fig. 7A) . The dual features of CD133 expression in hyperplastic podocytes and injured proximal tubules can support a final diagnosis of collapsing glomerulopathy (Fig. 7B) , particularly when hyperplastic podocytes are not florid and tubular cystic dilation is not obvious. CD133-positive hyperplastic podocytes may represent a common phenomenon seen over a spectrum of podocytopathies from FSGS to collapsing glomerulopathy in adults [18, 19] . Based on the CD133 staining patterns in both immature podocytes and proximal tubules, we suspect that some FSGS cases, such as case #9 in the FSGS group (Table 2) can be re-classified as a collapsing glomerulopathy. In collapsing glomerulopathy, the florid magnitude of immature hyperplastic podocytes (positively stained for CD133) appears to be an indirect index that reversely reflects sharply reduced functional podocytes (negative CD133 staining). 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