Glomerulonephritis PDF
Document Details
Uploaded by GenuineLlama
2005
Keith K. Lau, Robert J. Wyatt
Tags
Related
- Pathogenesis of Post-Streptococcal Glomerulonephritis PDF
- Glomerulonephritis Lecture - RPGN by Dr. Hisham
- Glomerulonephritis - 2024 PDF
- Glomerular Disorders In Glomerulonephritis And Nephrotic Syndrome Lecture I PDF
- Acute Kidney Injury, Glomerulonephritis (PDF)
- Medical-Surgical Nursing: Pyelonephritis and Glomerulonephritis PDF
Summary
This article discusses the clinical features and diagnostic evaluation of glomerulonephritis (GN) in adolescents. It covers the various types of GN, their diagnostic criteria, and treatment approaches. The article emphasizes the importance of early diagnosis and appropriate management to prevent long-term renal damage.
Full Transcript
Adolesc Med 16 (2005) 67 – 85 Glomerulonephritis Keith K. Lau, MDa,b, Robert J. Wyatt, MD, MSa,b,* a Division of Pediatric Nephrology, Department of Pediatrics, University of Tennessee...
Adolesc Med 16 (2005) 67 – 85 Glomerulonephritis Keith K. Lau, MDa,b, Robert J. Wyatt, MD, MSa,b,* a Division of Pediatric Nephrology, Department of Pediatrics, University of Tennessee Health Sciences Center, Room 301, WPT, 50 North Dunlap, Memphis, TN 38103, USA b Children’s Foundation Research Center at the Le Bonheur Children’s Medical Center, Room 301, WPT, 50 North Dunlap, Memphis, TN 38103, USA Early diagnosis of glomerulonephritis (GN) in the adolescent is important in initiating appropriate treatment and controlling chronic glomerular injury that may eventually lead to end-stage renal disease (ESRD). The spectrum of GN in adolescents is more similar to that seen in young and middle-aged adults than to that observed in prepubertal children. In this article, the authors discuss the clinical features associated with GN and the diagnostic evaluation required to determine the specific type of GN. With the exception of hereditary nephritis (Alport’s disease), virtually all types of GN are immunologically mediated with glomerular deposition of immunoglobulins and complement proteins. The inflammatory events leading to GN may be triggered by a number of factors. Most commonly, immune complexes deposit in the glomeruli or are formed in situ with the antigen as a structural component of the glomerulus. The immune complexes then initiate the production of proinflammatory mediators, such as complement proteins and cytokines. Subsequently, the processes of sclerosis within the glomeruli and fibrosis in the tubulointerstitial cells lead to chronic or even irreversible renal injury. Less commonly, these processes occur without involvement of immune complexes—so-called ‘‘pauci-immune GN.’’ * Corresponding author. Room 301, WPT, Children’s Foundation Research Center, 50 North Dunlap, Memphis, TN 38103. E-mail address: [email protected] (R.J. Wyatt). 1547-3368/05/$ – see front matter D 2005 Elsevier Inc. All rights reserved. doi:10.1016/j.admecli.2004.09.008 adolescent.theclinics.com 68 lau & wyatt Presentation and diagnostic evaluation The hallmark of GN is inflammation within the glomeruli that typically manifests as hematuria and proteinuria (Box 1). Renal function may be normal or reduced, depending on the severity of the acute condition or the presence of chronic glomerular injury. Patients often have a normal physical examination and blood pressure. However, sometimes they may present with any combination of oliguria, hypertension, and edema. Some types of GN have other associated findings, such as a vasculitic rash, arthritis, or even pulmonary hemorrhage. The hematuria can be macroscopic (visible) or microscopic. Microscopic examination of the urinary sediment characteristically shows dysmorphic red blood cells (RBCs) and often RBC casts. Dysmorphic RBCs can be detected with routine microscopy but are best detected by phase contrast microscopy. Greater than 30% of RBCs exhibiting dysmorphic features, such as doughnut shape and blebs, is a highly sensitive indicator of glomerular disease [2,3]. The degree of pro- teinuria may vary from normal (b 4 mg/m2/h) to nephrotic range (N 40 mg/m2/h). A random urine protein-to-creatinine ratio provides information as acceptable as that of a timed (usually 24-hour) collection, with normal being less than 0.2 and nephrotic range being greater than 2.0. Except in the typical case of poststreptococcal acute glomerulonephritis (PSAGN) with normal or transiently decreased renal function, renal biopsy is required to determine the precise diagnosis and severity of the glomerular involvement. Either consultation or referral to a nephrologist is necessary when the primary care physician suspects GN other than mild or typical cases of PSAGN. Certain blood tests will provide clues to the diagnosis and, in some instances, become markers for response to treatment. Baseline blood tests include complete blood count, creatinine, complement (C3 and C4), and streptococcal serology (antistreptolysin O and Streptozyme). Among all types of GN (Box 2), the ones associated with significant depression of serum C3 concentration are PSAGN, membranoproliferative glomerulonephritis (MPGN), systemic lupus erythematosus (SLE), nephritis of chronic bacteremia (ventriculo-atrial shunt and Box 1. Presenting signs and symptoms of glomerulonephritis Hematuria Macroscopic (visible) or microscopic Dysmorphic RBCs and RBC casts Proteinuria Hypertension Edema Renal insufficiency Transient Progressive glomerulonephritis 69 Box 2. Differential diagnosis of glomerulonephritis Poststreptococcal acute glomerulonephritis IgA nephropathies IgA nephropathy (Berger’s disease).. Henoch-Schonlein Membranoproliferative glomerulonephritis Idiopathic—types I, II, III Secondary—nephritis of chronic bacteremia, hepatitis B and C, alpha-1 antitrypsin deficiency, etc. C1q nephropathy Membranous nephropathy—typically presents with nephrotic syndrome Alport syndrome Antiglomerular basement membrane disease Antineutrophil cytoplasmic autoantibody (ANCA) glomerulonephritis Pauci-immune ANCA-negative glomerulonephritis Systemic lupus erythematosus subacute bacterial endocarditis), and hepatitis B GN. Significant C4 activation manifested by depression of serum C4 concentration is typically seen in SLE and sometimes in type I MPGN. The presence of systemic manifestations warrants a more extensive battery of diagnostic tests based on the diseases in the dif- ferential diagnosis (discussed later in this article for each specific disease). Principles of therapy Current treatment of GN has two main objectives: control of inflammation and inhibition of fibrosis. Anti-inflammatory agents include intravenous or oral cor- ticosteroids, cyclophosphamide, azathioprine, mycophenolate mofetil, and fish-oil supplements containing omega-3 fatty acids. Drugs that reduce proteinuria will inhibit tubular injury and fibrosis. These may include angiotensin-converting enzyme inhibitors (ACEi), angiotensin 2 receptor blockers (ARB), and perhaps statins and anti-oxidants. Specific treatments will be discussed in each section. Acute glomerulonephritis An adolescent with GN may present with signs and symptoms that require immediate intervention. One scenario is a presentation of renal insufficiency that 70 lau & wyatt worsens daily, as evidence accumulates that the patient does not have PSAGN. Such patients may have rapidly progressive GN (RPGN) that is characterized pathologically by crescents forming from the cells of Bowman’s capsule. If the process progresses, the crescent will irreversibly destroy the glomerular tuft. ESRD may occur within weeks of the onset of this process. This process is a true emergency that requires prompt referral to a nephrologist. Treatment with high- dose intravenous methylprednisolone and, in some cases, plasmapheresis may halt the process [4–7]. Another scenario is the occurrence of hypertensive encephalopathy or pulmonary edema at the onset of PSAGN. Adolescents who present with hypertension should be admitted to control the blood pressure and prevent these complications. Rapidly progressive glomerulonephritis RPGN may be diagnosed in the adolescent who presents with macroscopic hematuria and is found to have an elevated serum creatinine that continues to rise on a daily basis. Nonspecific symptoms such as fatigue and lethargy are common. Often the macroscopic hematuria persists until well after the initiation of treatment with intravenous methylprednisolone. Typically, more than 50% of the glomeruli should be affected with crescents for a case to be classified as RPGN. All of the immunologically mediated types of GN may present as RPGN, but the types most frequently associated with it are antiglomerular base- ment membrane (anti-GBM) disease, antineutrophil cytoplasmic autoantibodies (ANCA) GN, and Henoch-Schfnlein purpura nephritis (HSPN). PSAGN may also have crescent formation and in some cases will fit the definition of RPGN. The rarity of RPGN in children and adolescents is illustrated by a pediatric series that found crescents in 56 of 372 biopsy specimens, with only two meeting criteria for classification as RPGN. Often pediatric nephrologists will treat patients with fewer than 50% of glomeruli affected with crescents as if they had RPGN. Despite aggressive therapy, the outcome is often progression to ESRD. Early diagnosis and aggressive treatment are the most important factors in pre- servation of renal function. Poststreptococcal acute glomerulonephritis Early descriptions of PSAGN were based on the description of epidemics or clusters of cases usually related to pyoderma, with many cases being asymptomatic [10–12]. The peak age at occurrence was 4 to 5 years; few cases were diagnosed in adolescents. In the latest pediatric series from Memphis, only 11% were age 13 or older (S. Roy, personal communication, 2004). At the present time, cases tend to occur more sporadically, with more due to pharyngitis than to pyoderma, and the incidence in both the United States and other countries is declining [13–15]. The diagnosis of PSAGN is based on clinical features, depression of serum C3 concentrations, and the presence of streptococcal antibodies or enzymes in- glomerulonephritis 71 dicative of a recent infection with group A b-hemolytic streptococcus. At the time of clinical presentation, the throat culture is often negative. The anti- streptolysin O titer is significantly elevated in 50% to 80% of pharyngitis- associated cases. Antihyaluronidase and antideoxyribonuclease-B titers are elevated in pyoderma-associated cases. Ninety percent of patients have decreased serum C3 concentration acutely , with the level returning to normal within 4 to 8 weeks [17,18]. Renal biopsy is rarely required in patients with PSAGN. However, a renal biopsy is indicated in atypical situations, such as prolonged decrease in C3, recurrence of gross hematuria, progressive increase in proteinuria, and progressive deterioration in renal function. The clinical presentation of PSAGN is quite variable. Mild cases may have microscopic hematuria with no other symptoms, whereas severe cases can present with acute renal failure or hypertension, often accompanied by pulmonary edema. Infection with a nephritogenic strain of group A b-hemolytic streptococcus occurs over a week before the clinical onset of GN. The latent period is 1 to 2 weeks after pharyngitis and 3 to 6 weeks after onset of pyoderma. The typical presentation is hematuria, mild edema, and hypertension. Macroscopic hematuria occurs in over half of patients and may last for 1 to 2 weeks. In addition to dysmorphic RBCs and RBC casts, the urine sediment often has significant pyuria, with white blood cells seen within casts. Although proteinuria is usually found, it is not generally in the nephrotic range; less than 5% of patients with PSAGN have the nephrotic syndrome. Transient oliguria occurs in half of the patients, but renal failure requiring dialysis is unusual. Edema and hypertension are related to sodium retention and increased intravascular volume and generally respond to salt restriction and diuretic therapy. Hypertension usually resolves after several weeks. However, some patients may present with hypertensive encephalopathy manifested by some combination of headache, nausea, blurring of vision, seizures, and coma. Mild anemia due to hemodilution and leucocytosis is common, and the sedimentation rate is usually increased. The mainstay of treatment is still supportive. A low-salt diet is advised, but if significant edema and hypertension are present, a loop diuretic such as furosemide should be added. Only certain subtypes of the group A b-hemolytic streptococci are associated with GN. Pharyngitis-associated types are 1, 3, 4, 12, 25, and 49; pyoderma- associated types are 2, 49, 55, 57, and 60. Pharyngitis-associated PSAGN usually occurs in winter and early spring, whereas pyogenic-related PSAGN often happens in late summer. The typical histologic features are endocapillary proliferation with neutrophil infiltration. The glomeruli appear larger than normal, with capillary lumens that often are narrowed. Immunofluorescent stains show granular deposits of immune complex along the capillary wall and in the mesangium. These deposits are typi- cally composed of IgG, C3, and properdin, with occasional IgM and IgA. Electron microscopy shows large electron-dense ‘‘humps’’ in a subepithelial location. The humps and immune deposits disappear after resolution of the acute phase of PSAGN. It is still not clear whether the inflammation is caused by circulating immune complexes, complexes formed in situ, or both. The antigen or antigens 72 lau & wyatt that trigger the nephritogenic response and activate the alternative complement pathway are most likely related to specific nephritogenic M proteins. With the rare exception of severe crescentic PSAGN, which potentially may progress to ESRD, the outcome of PSAGN is excellent. The clinical signs usually resolve within several weeks, followed by cessation of proteinuria and hematuria. Microscopic hematuria may persist for several months, but the urinalysis is usually normal by 6 to 12 months. The occurrence of a second new case of PSAGN in the same child is well documented. Chronic or persistent glomerulonephritis Most types of GN will enter a chronic or persistent phase. Often such patients are at risk for continued glomerular injury that potentially could result in ESRD. Commonly, patients with GN that began in childhood or adolescence do not reach ESRD until adulthood. Progression to ESRD in adolescents with chronic GN may be delayed or even avoided with attention to the principles of reno- protection. This attention involves aggressive control of hypertension and treatment of proteinuria for both normotensive and hypertensive patients with an ACEi or an ARB. These agents are effective in reducing proteinuria in virtually all forms of chronic GN. Many adolescents and young adults exhibit poor com- pliance with regard to taking their medications. The primary care physician plays an important role in monitoring control of hypertension, encouraging compliance with medications, and stressing the importance of regular follow-up by the nephrologist. In addition, the physician should be aware of ACEi fetopathy as a major risk for pregnant adolescents so that the drug may be stopped immediately if the patient becomes pregnant. ACEi and ARB therapy should be used cau- tiously in adolescents at risk for dehydration, particularly in the football player involved in summer practice who has an increased risk for development of prerenal azotemia. IgA nephropathy IgA nephropathy (IgAN) is the most commonly diagnosed type of glomeru- lonephritis in the adolescent. Sixty-two percent of 47 patients at the authors’ institution were age 13 or older at the time of biopsy. In 1969 Jean Berger reported the finding of deposition of IgA in the mesangium of the glo- merulus in children and adults who experienced an episode of macroscopic hematuria during an episode of pharyngitis. This classic presentation of macroscopic hematuria at the time of a respiratory infection is the event that usually results in the referral of the adolescent to a nephrologist who performs the biopsy necessary for diagnosis. At the authors’ institution, they recommend a biopsy when the urine protein-creatinine ratio is more than 0.5. They sometimes glomerulonephritis 73 perform a biopsy with a lower degree of proteinuria when the child has recurrent macroscopic hematuria or when there is high parental anxiety and the urine sediment is consistent with GN (dysmorphic RBCs and RBC casts). IgAN differs from PSAGN in that the patient may be febrile at the time the hematuria begins, is normotensive or only mildly hypertensive, usually has normal renal function, and almost always has a normal or increased serum C3 concentration. How- ever, in Japan, only one third of patients with IgAN present with macroscopic hematuria; the others have asymptomatic microscopic hematuria or proteinuria. Some individuals with this presentation will have one or more episodes of macroscopic hematuria after diagnosis. Although severe hypertension is unusual early in the course of pediatric IgAN, according to norms based on age, gender, and height, about 20% of pediatric patients with IgAN are hypertensive at the time of diagnosis. A mild and transient reduction in renal function may occur either at presentation or during an episode of macroscopic hematuria [30,31]. However, in the United States, adolescents do not present with ESRD or chronic renal insufficiency (CRI) as frequently as adults. In the authors’ recent series, 2 of 29 adolescents presented with ESRD and one with mild CRI , as compared with over 40% of United States adult patients who had CRI at diagnosis [32,33]. The diagnosis of IgAN is based on the demonstration on renal biopsy of IgA as the dominant or codominant immunoglobulin in a predominantly mesangial deposition and on the absence of clinical evidence for any systemic disease, such as HSP or SLE. The immune deposits may also contain IgG or IgM and usually contain C3 and the alternative complement pathway protein, properdin. Evidence for classic complement pathway involvement with deposition of C1q or C4 appears in fewer than 10% of patients. No serologic test is specific for IgAN. Serum C3 and C4 levels are usually normal, and serum IgA level may be elevated in patients with the condition. The clinical course and eventual outcome of IgAN are quite variable [29,31]. Many adolescents have recurrent episodes of macroscopic hematuria during viral respiratory illnesses. These episodes may subside after several years. Long-term follow-up of patients diagnosed with IgAN in childhood and adolescence indicates that between 25% and 50% will enter a remission phase in which the renal function and urinalysis are normal [27,29,36]. In contrast, life-table analysis of data from over 100 pediatric patients followed in Lexington, Kentucky and Memphis predicted that 15% would progress to ESRD 10 years from onset and 30% after 20 years. Patients should be followed particularly closely if they have prognostic markers associated with progression to ESRD. These markers include severe biopsy findings such as sclerotic lesions within the glomeruli, a urine protein-to- creatinine ratio persistently greater than 1.0, and hypertension [29,31,32]. African American children and adolescents were previously thought to have worse outcomes than white children [31,37], but since 1990 the authors have diagnosed more African Americans and find no difference in progression to ESRD based on race. 74 lau & wyatt Currently, treatment of IgAN in adolescents is not guided by results of well- designed randomized control trials (RCTs) that employ appropriate outcome measures. The first choice for treatment of hypertension is an ACEi. Ado- lescents with a urine protein-to-creatinine ratio greater than 1.0 after 3 months of ACEi therapy may benefit from additional therapy. Several regimens of daily, alternate-day, and even intravenous steroids have been used to treat children and adults with IgAN. This treatment is problematic, because adolescents have a low tolerance for the side effects of Cushingoid facies, weight gain, and exacerbation of acne. Fish oil supplements (FOS) have been widely used in adults with IgAN and appear to slow the progression to ESRD in both patients with normal renal function and CRI. The North American IgAN Study Group examined FOS versus alternate-day prednisone versus placebo in patients under age 40 with the primary endpoint of decline in kidney function. This study found no significant difference with regard to decline in renal function among the alternate-day prednisone, FOS, and placebo groups. However, proteinuria declined significantly after 2 years of treatment for both the prednisone and FOS groups as compared with the placebo group. Mycophenolate mofetil (MMF) suppresses antibody formation by B cells through impairment of de novo purine synthesis. Case series suggested that MMF may reduce proteinuria in a variety of glomerular diseases, including IgAN [43,44]. The North American IgAN Study Group recently began a multicenter RCT designed to test the hypothesis that treatment with MMF improves proteinuria in patients with IgAN who were pretreated and continued to be treated with ACEi and FOS, as compared with a placebo control group of patients receiving comparable doses of ACEi and FOS without MMF. Although the pathogenetic mechanisms involved in the development and clinical expression of IgAN have yet to be fully elucidated, there appears to be a primary event involving aberrantly glycosylated IgA1 molecules (deficient in galactose in O-linked glycans of the hinge regions). These deposit are found in the glomeruli [46,47] and in circulating immune complexes of patients with IgAN. Most patients with IgAN do not have a familial history of kidney disease. However, familial occurrences of IgAN have been described in Kentucky [49,50] and in northern Italy. Numerous pedigrees with first-, second-, and third- degree relatives having IgAN or HSPN have also been reported. Studies in the pedigrees from Italy and Kentucky showed that half of them had linkage between probable and biopsy-proven cases and a locus on chromosome 6. This finding provides hope that further investigation will find a gene or genes associated with IgAN. Deposits of IgA frequently recur in the allograft soon after transplant into a patient with IgAN. Clinically important recurrence of IgAN is unusual within several years of transplant. However, there is a significant late risk of graft loss, often in the second decade after transplant. Transplantation is still recommended for adolescents with ESRD due to IgAN. However, care should be taken to exclude mild or subclinical IgAN in potential living donors. glomerulonephritis 75.. Henoch-Schonlein purpura nephritis HSP is a vasculitic disease with typical petechial and purpuric lesions that occur predominantly on the lower extremities and buttocks. Other symptoms commonly seen at presentation are abdominal pain and arthritis or arthralgia, particularly in the knees and ankles. Often the urinalysis is normal at pre- sentation, with microscopic hematuria and proteinuria developing within the subsequent 3 months. Adolescents with a normal urinalysis at diagnosis should have a urinalysis performed at weekly intervals for 4 weeks and again at months 2 and 3 from onset. The development of microscopic hematuria or proteinuria warrants referral to a nephrologist. The peak age for development of HSP is early childhood (age 4–6 years), with onset in adolescence and adulthood being less common. Many children with HSP never develop clinically apparent GN. Early experience suggested that presen- tation in late childhood and adolescence was related to the severity of GN at presentation , but subsequent reports found no correlation between age at presentation and outcome [56,57]. HSPN and IgAN share common pathogenetic factors. The renal biopsy findings are indistinguishable, with both conditions having prominent mesangial deposition of IgA. However, HSPN is more likely than IgAN to have capillary loop immune deposits and significant crescentic involvement. After simultaneous adenovirus infections in previously healthy identical twins, one had the clinical phenotype of HSP and the other had only macroscopic hematuria, but both had mesangial IgA deposits. As mentioned previously, IgAN and HSPN sometimes occur in closely related individuals. HSPN has developed in children previously proved or suspected to have IgAN based on episodes of isolated macroscopic hematuria. Some children being followed for HSPN will experience one or more episodes of macroscopic hematuria at the time of an upper respiratory illness in the absence of rash, joint, or abdominal symptoms. The aberrantly glycosylated IgA1 molecules found in IgAN are also present in patients with HSPN. Virtually all data on treatment of HSPN derive from case series. Cres- centic or RPGN is usually treated with high-dose methylprednisolone, often with the addition of other immunosuppressive medications such as cyclophosphamide. In many instances HSPN will resolve over time. However, some patients will have persistence of microscopic hematuria and proteinuria. Treatment in such cases should be similar to that of IgAN, with ACEi or ARB and consideration of other agents, such as FOS or alternate-day prednisone. Membranoproliferative glomerulonephritis MPGN, also known as mesangiocapillary GN, was first described in 1965 when West et al made the association between persistent hypocomple- mentemia (low C3 concentration) and light microscopic features of severe mesangial proliferation with thickening of the capillary walls. Because the hypo- 76 lau & wyatt complementemia occurs in only 75% of patients with MPGN, normal serum levels of complement proteins cannot exclude the diagnosis. Based upon glo- merular morphology, MPGN can be divided into three types that may represent distinct disorders. MPGN is an infrequently occurring form of GN; in most parts of the world its incidence appears to be declining. However, the peak age for onset of the disease is in the adolescent years. The three most common clinical presentations of MPGN are asymptomatic proteinuria with microscopic hematuria, acute nephritic onset, and the nephrotic syndrome [63–65]. Patients detected in the earliest stages of MPGN are most likely to present with asymptomatic protein- uria and hematuria. An acute nephritic onset may mimic PSAGN, but MPGN should be suspected in patients whose serum C3 concentration does not return to normal within 6 weeks of onset. Adolescents with macroscopic hematuria, hypertension, and the nephrotic syndrome are more likely to have MPGN than PSAGN and should have a renal biopsy at presentation. MPGN is the likely diagnosis for an adolescent with new-onset nephrotic syndrome, a low serum C3, and no evidence of SLE. Nephrotic syndrome at presentation is a marker of poor prognosis [64,65]. Most adolescents with MPGN are hypertensive at presenta- tion, but severe hypertension is unusual. Type I MPGN is characterized by granular immune complex deposition in the mesangium capillary loops with interposition of the mesangium between the endothelium and the basement membrane; it resembles a duplication of the membrane. The immune deposits seen on electron microscopy are in a sub- endothelial location and usually can be shown to contain IgG, IgM, C1q, C4, and C3 by immunofluorescent staining. The serum C4 concentration may be mildly depressed, but usually not to the extent seen in active SLE. These findings suggest that, in MPGN, immune complexes activate the classic com- plement pathway. Type II MPGN is characterized by activation of the alternative complement pathway by C3 nephritic factor (C3Nef), an autoantibody to the C3 convertase (C3b, Bb) [67,68]. The presence of C3Nef leads to continuous consumption of C3 that appears to precede the development of GN. Other conditions associated with the presence of C3Nef, such as partial lipodystrophy, place an affected individual at risk for developing type II MPGN. Electron microscopy shows electron-dense deposits within the glomerular basement membrane; some investigators believe that these represent an alteration of the basement membrane rather than true immune deposits. Immunofluorescent studies show that these basement membranes stain for C3, with or without IgG or IgM staining. Typically, serum levels of C3 are markedly depressed, with levels of C4 and C5 remaining normal. Type III MPGN is characterized by electron-dense deposits that are within and on both sides of the basement membrane (subendothelial and subepithelial). A C3Nef that converts C3 more slowly and activates the terminal complement components has been found in patients with type III MPGN. Serum C3 levels are typically decreased, with C4 level normal. Type III MPGN has been glomerulonephritis 77 linked to chromosome 1q31–32 in a four-generation Irish pedigree containing eight affected individuals. Secondary MPGN has occurred in association with such conditions as ne- phritis of chronic bacteremia, hepatitis B, hepatitis C, and alpha-1 antitrypsin deficiency. In such instances, treatment should be directed, if possible, toward the primary disease. The outcome is not good for all three types of MPGN, with perhaps 50% of patients reaching ESRD within 10 years of diagnosis. Furthermore, few treatment data from RCTs are available. Uncontrolled experience at Cincinnati Children’s Hospital has been used to advocate long-term alternate-day prednisone for treatment of all three types of MPGN. Data from the International Study of Kidney Diseases in Childhood trial of alternate-day prednisone compared with placebo showed significantly better survival for steroid-treated patients with types I and III MPGN, but not type II. These studies were performed long before the routine administration of ACEi or ARB for control of hypertension and treatment of proteinuria. Currently it is difficult, if not impossible, to provide strong evidence-based recommendations for treatment of adolescents with MPGN. However, ACEi or ARB for all types and a course of alternate- day prednisone, particularly for patients with type I MPGN, appear prudent. MPGN, particularly types I and II, often recurs after a renal transplant and may lead to loss of the allograft [77,78]. Newer immunosuppressive agents such as MMF may assume a role in the treatment of MPGN , but the apparent decline in the incidence of MPGN makes it unlikely that RCTs will be organized in the near future. C1q nephropathy Jennette and Hippe described C1q nephropathy in 1985 as a distinct pathologic entity in which patients with steroid-resistant nephrotic syndrome had mesangial deposits where C1q was the dominant or codominant reactant. Electron-dense deposits that appear similar to those seen in IgAN are also found in the mesangium. No clinical or pathologic evidence of MPGN, membranous nephropathy, or SLE is seen. At the authors’ center, only 57% of the 21 cases had nephrotic syndrome at presentation. The majority (62%) of their patients were adolescents, with 57% being African American and 57% male. Nephrotic- range proteinuria in the absence of the nephrotic syndrome was found in another 29%. The remaining 14% had only proteinuria or hematuria at presentation. Patients with C1q nephropathy often progress to ESRD, particularly when the nephrotic syndrome persists. Treatment with corticosteroids and other immune- suppressant agents such as cyclosporine A has been attempted. Membranous nephropathy The majority of pediatric patients with idiopathic membranous nephropathy present with nephrotic syndrome. The Southwest Pediatric Nephrology Study 78 lau & wyatt Group found that only 15% of 54 patients were not nephrotic at presentation. Presumably, some of these nonnephrotic patients had microscopic hematuria. Hence, membranous GN should be considered in the differential diagnosis of GN in the adolescent. Alport syndrome Alport syndrome is a hereditary defect of glomerular basement membranes that results in hematuria and may progress to ESRD. Diagnosis is often made after examination of the urinalysis in a child from a family with multiple cases of hereditary nephritis. Thus, most adolescents with the condition are now diagnosed early. Children may initially present with heavy microscopic hema- turia (large blood on dipstick), followed by the development of proteinuria. Adolescents with Alport syndrome may have persistent macroscopic hematuria or even episodic occurrences, as seen in IgAN, at the time of intercurrent infection. Many, but not all, individuals with Alport’s syndrome also have sensorineural deafness and ocular defects. The hearing loss is bilateral and often first detected during adolescence. Conical protrusion on the anterior aspect of the lens (anterior lenticonus) is the most common manifestation of the eye defect. Cataracts may develop after a minor traumatic event. About 80% of patients are from kindreds with an X-linked dominant pattern of inheritance, whereas others have autosomal recessive or autosomal dominant patterns. In the X-linked pedigrees, usually the males have more severe disease than the females. Affected males usually progress to ESRD as adults, but progression sometimes occurs during adolescence. Because of X-chromosome inactivation, many females will never have more than microscopic hematuria with or without mild proteinuria. However, some females do have more significant clinical disease and may even progress to ESRD. Renal biopsy is often nondiagnostic in the young child. At a later stage of the disease, light microscopic examination of the kidney tissue may show mesangial enlargement, glomerulosclerosis, tubulo-interstitial fibrosis, and prominent interstitial foam cells. The diagnostic pathologic lesion is the electron micro- scopic demonstration of irregular thinned and thickened areas of the basement membrane, with splitting and splintering. However, only the thinning of the basement membrane may be seen at early stages, and some patients with typical clinical Alport’s syndrome have only basement-membrane thinning, even at advanced stages. The underlying defect in Alport’s syndrome is in type IV collagen. Unique mutations are found in different families with Alport’s and may partially explain the observed heterogeneity in presentation and progression. The X-linked form of Alport’s syndrome has the mutation in the COL4A5 gene. Families with the autosomal recessive form of Alport’s syndrome have mutations in COL4A3 or COL4A4 on chromosome two. Progression to ESRD in patients with Alport’s syndrome is difficult if not impossible to prevent. Proteinuria may be reduced and renal function glomerulonephritis 79 stabilized by treatment with either cyclosporine A or ACEi. Patients with Alport’s syndrome who progress to ESRD are usually good candidates for renal transplant, although there is a small risk of developing anti-GBM GN in the allograft. Antiglomerular basement membrane disease Anti-GBM (Goodpasture’s) disease usually presents as RPGN; 60% of cases have pulmonary hemorrhage. Although anti-GBM disease is very rare, the ability to diagnose and aggressively treat the condition may prevent fatal complications. The incidence of anti-GBM disease in Europe was 0.5 cases per 1 million persons per year. Only one adolescent with anti-GBM disease has been diagnosed at the authors’ center in the past 20 years. Anti-GBM disease may be first diagnosed by a renal biopsy that shows linear deposition of IgG along the glomerular capillary loop. Specific anti-GBM antibodies are found in the serum but do not always correlate with disease activity. These antibodies react against an epitope in the NC-1 domain of the alpha-3 chain of type IV collagen. Some patients may have a negative serology, and the diagnosis is made by biopsy alone. When anti-GBM disease is diagnosed, treatment is begun with intravenous corticosteroids and plasma exchange, followed by oral corticosteroids and cyclo- phosphamide. The goal of treatment is removal of anti-GBM antibodies and suppression of antibody formation. If the disease is diagnosed early, patients may be able to maintain normal renal function. Patients with more advanced disease may receive a renal transplant after anti-GBM antibodies become negative. Antineutrophil cytoplasmic autoantibody glomerulonephritis ANCA GN was first described in 1982 in adults with necrotizing GN. ANCA represents a family of autoantibodies against constituents in the neutro- phil cytoplasm. The primary antigens for these autoantibodies are proteinase 3 (anti-PR3) and myeloperoxidase (anti-MPO). ANCA GN is characterized by a vasculitis affecting renal arterioles and glomerular capillaries. The vasculitis may be limited to the kidney or include other organ systems, particularly the skin and lungs. Adolescents may present with various symptoms, such as malaise, sinusitis, myalgia, arthralgia, and rash [93,94]. The rash may mimic the palpable purpura of HSP or be more extensive, with ecchymoses and ulcerations. The systemic vasculitis may also manifest as abdominal pain with intestinal bleeding and peripheral neuropathy. In a recent pediatric series of 31 Japanese children with ANCA GN, almost half were over age 13 and most were female. The morbidity of pediatric ANCA-GN is high, particularly if the patient has renal insufficiency at diagnosis. In the Japanese report, almost 50% had ESRD or CRI with a mean follow- up of 42 months. No evidence-based guidelines are available for treatment of 80 lau & wyatt children with ANCA GN. Treatment in children with or without other systemic involvement usually consists of intravenous methylprednisone, followed by oral prednisone and additional immunosuppression with cyclophosphamide or azathioprine. Prolonged maintenance treatment with these agents is indicated until long after remission has been achieved with negative ANCA. Pauci-immune glomerulonephritis Before the development of a classification system for ANCA-associated GN , most cases of ANCA GN were classified as pauci-immune GN or idiopathic crescentic GN. Some adolescents with crescentic GN will have negative or sparse glomerular deposits of immunoglobulins or complement components, as well as negative anti-PR3 and anti-MPO antibodies. As in ANCA GN, serum C3 concentration is normal. The approach to treatment of such patients is similar to that of ANCA GN, but without the benefit of a serologic marker to assess response to treatment. Thus, treatment must be guided by improvement in proteinuria and systemic markers of inflammation such as erythrocyte sedimen- tation rate and C reactive protein. Systemic lupus erythematosus SLE is an important cause of GN in the adolescent, with females affected much more frequently than males. Discussion of the diagnosis and clinical course of SLE in the adolescent is beyond the scope of this review. SLE will occasionally present in the adolescent as GN without other clinical SLE features, such as malar rash and arthritis. Marked depression of serum C4 and C3 concentrations in a patient with GN is highly suggestive of SLE, because extremely low levels of C4 are unusual for other types of GN. Renal biopsy is recommended for patients with SLE who have an abnormal urinalysis and significant urinary protein excretion. This measure makes it possible to determine the renal histologic class that is used to guide the initial treatment. The 2003 classification of lupus nephritis by the International Society of Nephrology and Renal Pathology Society is based on the original World Health Organization system. This system uses the following major headings: Class I— minimal mesangial lupus nephritis, Class II—mesangial proliferative lupus nephritis, Class III—focal lupus nephritis, Class IV—diffuse lupus nephritis, Class V—membranous lupus nephritis, and Class VI—advanced sclerosis lupus nephritis. GN is the major cause of long-term morbidity in SLE and, if not controlled, may lead to ESRD. Prognostic indicators for progression to ESRD include severity of the renal histologic involvement and black race [97–99]. Oral corticosteroids and ACEi may be sufficient therapy for mild GN (Classes I and II). For many patients with Class III and IV histology, treatment protocols involve such immunosuppressive agents as intravenous cyclophospha- mide or oral MMF [100–103]. Clinicians caring for adolescents with SLE GN glomerulonephritis 81 should be aware of the potential complications of these immunosuppressive agents, such as bone marrow depression and opportunistic infections. Summary GN in the adolescent requires prompt diagnosis. When even mild degrees of renal insufficiency are documented, immediate referral to a nephrologist is necessary to ensure that serious conditions, such as RPGN, are correctly di- agnosed and aggressively managed. In an adolescent with macroscopic hema- turia, the demonstration of dysmorphic RBCs, RBC casts, and proteinuria indicates that the bleeding is of glomerular origin. Physicians caring for adolescents with chronic GN should have a basic understanding of the specific disorders. They may be involved in blood pressure monitoring and should be aware of the potential side effects of the antihypertensive and immunosuppressive medications used in patients with GN. References Eddy A. Molecular basis of renal fibrosis. Pediatr Nephrol 2000;15:290 – 301. Crompton CH, Ward PB, Hewitt IK. The use of urinary red cell morphology to determine the source of hematuria in children. Clin Nephrol 1993;39:44 – 9. Dinda AK, Saxena S, Guleria S, et al. Diagnosis of glomerular haematuria: role of dysmor- phic red cell, G1 cell and bright-field microscopy. Scand J Clin Lab Invest 1997;57:203 – 8. Bolton WK, Sturgill BC. Methylprednisolone therapy for acute crescentic rapidly progres- sive glomerulonephritis. Am J Nephrol 1989;9:368 – 75. Bolton WK. Rapidly progressive glomerulonephritis. Semin Nephrol 1996;16:517 – 26. Cole BR, Brocklebank JT, Kienstra RA, et al. ‘‘Pulse’’ methylprednisolone therapy in the treatment of severe glomerulonephritis. J Pediatr 1976;88:307 – 14. Kaplan AA. Therapeutic plasma exchange for the treatment of rapidly progressive glomerulonephritis. Ther Apher 1997;1:255 – 9. Southwest Pediatric Nephrology Study Group. A clinico-pathological study of crescentic glo- merulonephritis in 50 children. Kidney Int 1985;27:450 – 8. Miller MN, Baumal R, Poucell S, et al. Incidence and prognostic importance of glomerular crescents in renal diseases of childhood. Am J Nephrol 1984;4:244 – 7. Fish AJ, Herdman RC, Michael AF, et al. Epidemic acute glomerulonephritis associated with type 49 streptococcal pyoderma. II. Correlative study of light, immunofluorescent and electron microscopic findings. Am J Med 1970;48:28 – 39. Peter G, Smith AL. Group A streptococcal infections of the skin and pharynx (first of two parts). N Engl J Med 1977;11:311 – 7. Roy III S, Pitcock JA, Etteldorf JN. Prognosis of poststreptococcal glomerulonephritis in childhood: prospective study and review of the literature. Adv Pediatr 1976;23:35 – 69. Bodaghi E, Vazirian S, Abtahi M, et al. Glomerular diseases in children. The Iranian experience. Pediatr Nephrol 1989;3:213 – 7. Roy III S, Stapleton FB. Changing perspectives in children hospitalized with poststreptococcal acute glomerulonephritis. Pediatr Nephrol 1990;4:585 – 8. Yap HK, Chia KS, Murugasu B, et al. Acute glomerulonephritis—changing patterns in Singapore children. Pediatr Nephrol 1990;4:482 – 4. 82 lau & wyatt Strife CF, McAdams AJ, McEnery PT, et al. Hypocomplementemic and normocomplemente- mic acute nephritis in children: a comparison with respect to etiology, clinical manifestations, and glomerular morphology. J Pediatr 1974;84:29 – 38. Cameron JS, Vick RM, Ogg CS, et al. Plasma C3 and C4 concentrations in management of glomerulonephritis. BMJ 1973;3:668 – 72. Wyatt RJ, Forristal J, West CD, et al. Complement profiles in acute post-streptococcal glomerulonephritis. Pediatr Nephrol 1988;2:219 – 23. Hinglais N, Garcia-Torres R, Kleinknecht D. Long-term prognosis in acute glomerulonephritis. The predictive value of early clinical and pathological features observed in 65 patients. Am J Med 1974;56:52 – 60. Tejani A, Ingulli E. Poststreptococcal glomerulonephritis: current clinical and pathologic concepts. Nephron 1990;55:1 – 5. Nissenson AR, Baraff LJ, Fine RJ, et al. Poststreptococcal acute glomerulonephritis: fact and controversy. Ann Intern Med 1979;91:76 – 86. Sagel I, Treser G, Ty A, et al. Occurrence and nature of glomerular lesions after group A streptococci infections in children. Ann Intern Med 1973;79:492 – 9. Tornroth T. The fate of subepithelial deposits in acute poststreptococcal glomerulonephritis. Lab Invest 1976;35:461 – 74. Villarreal Jr H, Fischetti VA, van de Rijn I, et al. The occurrence of a protein in the extracellu- lar products of streptococci isolated from patients with acute glomerulonephritis. J Exp Med 1979;149:459 – 72. Roy III S, Wall HP, Etteldorf JN. Second attacks of acute glomerulonephritis. J Pediatr 1969; 75:758 – 67. Hebert LE, Wilmer WA, Falkenheim ME, et al. Renoprotection: one or many therapies? Kidney Int 2001;59:1211 – 23. Lau KK, Gaber LW, Delos Santos NM, et al. Pediatric IgA nephropathy: clinical features at presentation and outcome for African-Americans and Caucasians. Clin Nephrol 2004;62(3): 167 – 72. Berger J. IgA glomerular deposits in renal disease. Transplant Proc 1969;1:939 – 44. Yoshikawa N, Ito H, Yoshiara S, et al. Clinical course of IgA nephropathy in children. J Pediatr 1987;110:555 – 60. Wyatt RJ, Julian BA, Bhathena DB, et al. IgA nephropathy: presentation, clinical course, and prognosis in children and adults. Am J Kidney Dis 1984;4(2):192 – 200. Wyatt RJ, Kritchevsky SB, Woodford SY, et al. IgA nephropathy: long-term prognosis for pediatric patients. J Pediatr 1995;127:913 – 9. Haas M. Histological subclassification of IgA nephropathy: a clinicopathologic study of 244 cases. Am J Kidney Dis 1997;29:829 – 42. Wyatt RJ, Julian BA, Baehler RW, et al. Epidemiology of IgA nephropathy in central and eastern Kentucky for the period 1975 through 1994. J Am Soc Nephrol 1998;9:853 – 8. Wyatt RJ. The complement system in IgA nephropathy and Henoch-Schfnlein purpura: functional and genetic aspects. Contrib Nephrol 1993;104:82 – 91. Julian BA, Wyatt RJ, McMorrow RG, et al. Serum complement proteins in IgA nephropathy. Clin Nephrol 1993;20:251 – 8. Delos Santos NM, Wyatt RJ. Pediatric IgA nephropathy: clinical aspects and therapeutic approaches. Semin Nephrol 2004;24(3):269 – 86. Hogg RJ, Silva FG, Wyatt RJ, et al. Prognostic indicators in children with IgA nephropathy— report of the Southwest Pediatric Nephrology Study Group. Pediatr Nephrol 1994;8:15 – 20. Wyatt RJ, Hogg RJ. Evidence-based assessment of treatment options for children with IgA nephropathies. Pediatr Nephrol 2001;16:157 – 66. Donadio Jr JV, Bergstralh EJ, Offord KP, et al. A controlled trial of fish oil in IgA nephropathy. Mayo Nephrology Collaborative Group. N Engl J Med 1994;331:1194 – 9. Hogg RJ for the Scientific Planning Committee of the IgA Nephropathy Study. A randomized, placebo-controlled, multicenter trial evaluating alternate-day prednisone and fish oil sup- glomerulonephritis 83 plements in young patients with immunoglobulin A nephropathy. Am J Kidney Dis 1995;26: 792 – 6. Hogg RJ, Lee J, Nardelli NA, et al. Multicenter placebo-controlled trial of alternate-day prednisone (QOD-PRED) or daily omega-3 fatty acids (OM-3 FA) in children and young adults with IgA nephropathy (IgAN). Report from the Southwest Pediatric Nephrology Study Group. J Am Soc Nephrol 2003;14:751A. Eugui EM, Mirkovich A, Allison AC. In vitro immunosuppressive effects of mycophenolic acid and an ester pro drug, RS-61443. Transplant Proc 1991;23(Suppl 2):10 – 4. Bayazit AK, Noyan A, Cengiz N, et al. Mycophenolate mofetil in children with multidrug- resistant nephrotic syndrome. Clin Nephrol 2004;61:25 – 9. Nowack R, Birck R, van der Woude FJ. Mycophenolate mofetil for systemic vasculitis and IgA nephropathy. Lancet 1997;349:1774. Hogg RJ, Wyatt RJ. A randomized controlled trial of mycophenolate mofetil in patients with IgA nephropathy. Biomedical Central Nephrology 2004;5:3. Allen AC, Willis FR, Beattie TJ, et al. Abnormal IgA glycosylation in Henoch-Schfnlein purpura restricted to patients with clinical nephritis. Nephrol Dial Transplant 1998;13:930 – 4. Hiki Y, Odani H, Takahashi M. Mass spectrometry proves under O-glycosylation of glomeru- lar IgA1 in IgA nephropathy. Kidney Int 2001;59:1077 – 85. Tomana M, Novak J, Julian BA, et al. Circulating immune complexes in IgA nephropathy consist of IgA1 with galactose-deficient hinge region and antiglycan molecules. J Clin Invest 1999;104:73 – 81. Julian BA, Quiggins PA, Thompson JS, et al. Familial IgA nephropathy. Evidence of an inherited mechanism of disease. N Engl J Med 1985;312:202 – 8. Wyatt RJ, Rivas ML, Julian BA, et al. Regionalization in hereditary IgA nephropathy. Am J Hum Genet 1987;41:36 – 50. Scolari F, Amoroso A, Savoldi S, et al. Familial clustering of IgA nephropathy: further evi- dence in an Italian population. Am J Kidney Dis 1999;33:857 – 65. Levy M. Multiplex families in IgA nephropathy. Contrib Nephrol 1993;104:46 – 53. Gharavi AG, Yan Y, Scolari F, et al. IgA nephropathy, the most common cause of glomerulonephritis, is linked to 6q22–23. Nat Genet 2000;26:354 – 7. Choy BY, Chan TM, Lo SK, et al. Renal transplantation in patients with primary immunoglobulin A nephropathy. Nephrol Dial Transplant 2003;18:2399 – 404. Counahan R, Winterborn MH, White RH, et al. Prognosis of Henoch-Schfnlein nephritis in children. BMJ 1977;2:11 – 4. Coppo R, Mazzucco G, Cagnoli L, et al. Long-term prognosis of Henoch Schfnlein nephritis in adults and children. Nephrol Dial Transplant 1997;12:2277 – 83. Scharer K, Krmar R, Querfeld U, et al. Clinical outcome of Schfnlein-Henoch purpura nephritis in children. Pediatr Nephrol 1999;13:816 – 23. Levy M, Broyer M, Arsan A, et al. Anaphylactoid purpura nephritis in childhood: natural history and immunopathology. Adv Nephrol 1976;6:183 – 228. Meadow SR, Scott DG. Berger disease: Henoch-Schfnlein syndrome without the rash. J Pediatr 1985;106:27 – 31. Waldo FB. Is Henoch-Schfnlein purpura the systemic form of IgA nephropathy? Am J Kidney Dis 1988;12:373 – 7. Watanabe T, Takada T, Kihara I, et al. Three cases of Henoch-Schfnlein purpura preceded by IgA nephropathy. Pediatr Nephrol 1995;9:674. West CD, McAdams AJ, McConville JM, et al. Hypocomplementemic and normocomplemen- temic persistent nephritis: clinical and pathological characteristics. J Pediatr 1965;67:1089 – 112. West CD. Idiopathic membranoproliferative glomerulonephritis in childhood. Pediatr Nephrol 1992;6:96 – 103. Cameron JS, Turner DR, Heaton J, et al. Idiopathic mesangiocapillary glomerulonephri- tis. Comparison of types I and II in children and adults and long-term prognosis. Am J Med 1983;74:175 – 92. 84 lau & wyatt Habib R, Kleinknecht C, Gubler MC, et al. Idiopathic membranoproliferative glomerulone- phritis in children. Report of 105 cases. Clin Nephrol 1973;1:194 – 214. Wyatt RJ, McAdams AJ, Forristal J, et al. Glomerular deposition of complement-control proteins in acute and chronic glomerulonephritis. Kidney Int 1979;16:505 – 12. Spitzer RE, Vallota EH, Forristal J, et al. Serum C’3 lytic system in patients with glomerulonephritis. Science 1969;164:436 – 7. Williams DG. C3 nephritic factor and mesangiocapillary glomerulonephritis. Pediatr Nephrol 1997;11:96 – 8. Misra A, Peethambaram A, Garg A. Clinical features and metabolic and autoimmune derangements in acquired partial lipodystrophy: report of 35 cases and review of the literature. Medicine (Baltimore) 2004;83:18 – 34. Galle P, Mahieu P. Electron dense alteration of kidney basement membranes. A renal lesion specific of a systemic disease. Am J Med 1975;58:749 – 64. Clardy CW, Forristal J, Strife CF, et al. A properdin-dependent nephritic factor slowly activating C3, C5 and C9 in membranoproliferative glomerulonephritis types I and III. Clin Immunol Immunopathol 1989;50:333 – 47. Neary JJ, Conlon PJ, Croke D, et al. Linkage of a gene causing familial membranoprolifera- tive glomerulonephritis type III to chromosome 1. J Am Soc Nephrol 2002;13:2052 – 7. Ozdamar S, Gucer S, Tinaztepe K. Hepatitis-B virus associated nephropathies: a clinicopatho- logical study in 14 children. Pediatr Nephrol 2003;18:23 – 8. McEnery PT, McAdams AJ, West CD. The effect of prednisone in a high-dose, alternate- day regimen on the natural history of idiopathic membranoproliferative glomerulonephritis. Medicine (Baltimore) 1985;64:401 – 24. Tarshish P, Bernstein J, Tobin JN, et al. Treatment of mesangiocapillary glomerulonephritis with alternate-day prednisone—a report of the International Study of Kidney Disease in Children. Pediatr Nephrol 1992;6:123 – 30. Levin A. Management of membranoproliferative glomerulonephritis: evidence-based recom- mendations. Kidney Int Suppl 1999;70:S41 – 6. Curtis JJ, Wyatt RJ, Bhathena D, et al. Renal transplantation for patients with type I and type II membranoproliferative glomerulonephritis: serial complement and nephritic factor measure- ments and the problem of recurrence of disease. Am J Med 1979;66:216 – 25. Shimizu T, Tanabe K, Oshima T, et al. Recurrence of membranoproliferative glomerulone- phritis in renal allografts. Transplant Proc 1998;30:3910 – 3. Jennette JC, Hipp CG. C1q nephropathy: a distinct pathologic entity usually causing nephritic syndrome. Am J Kidney Dis 1985;6:103 – 10. Lau KK, Gaber LW, Wyatt RJ, et al. Pediatric C1q nephropathy: clinical presentation and outcome. J Am Soc Nephrol 2004;15:A555 – 6. Hogg RJ for the Southwest Pediatric Nephrology Study Group. Comparision of idiopathic and systemic lupus erythematosus–associated membranous glomerulopathy in children. Am J Kidney Dis 1986;7:115 – 24. Kashtan CE. Alport syndromes: phenotypic heterogeneity of progressive hereditary nephritis. Pediatr Nephrol 2000;14:502 – 12. Hudson BG, Reeders ST, Tryggvason K. Type IV collagen: structure, gene organization, and role in human diseases. Molecular basis of Goodpasture and Alport syndromes and diffuse leiomyomatosis. J Biol Chem 1993;268:26033 – 6. Longo I, Porcedda P, Mari F, et al. COL4A3/COL4A4 mutations: from familial hematuria to autosomal-dominant or recessive Alport syndrome. Kidney Int 2002;61:1947 – 56. Callis L, Vila A, Carrera M, et al. Long-term effects of cyclosporine A in Alport’s syndrome. Kidney Int 1999;55:1051 – 6. Proesmans W, Knockaert H, Trouet D. Enalapril in paediatric patients with Alport syndrome: 2 years’ experience. Eur J Pediatr 2000;159:430 – 3. McCoy RC, Johnson HK, Stone WJ, et al. Absence of nephritogenic GBM antigen(s) in some patients with hereditary nephritis. Kidney Int 1982;21:642 – 52. glomerulonephritis 85 Kluth DC, Rees AJ. Anti-glomerular basement membrane disease. J Am Soc Nephrol 1999;10: 2446 – 53. Kalluri R, Sun MJ, Hudson BG, et al. The Goodpasture autoantigen: structural delineation of two immunologically privileged epitopes on alpha3(IV) chain of type IV collagen. J Biol Chem 1996;271:9062 – 8. Levy JB, Turner AN, Rees AJ, et al. Long-term outcome of anti-glomerular basement membrane antibody disease treated with plasma exchange and immunosuppression. Ann Intern Med 2001;134:1033 – 42. Davies DJ, Moran JE, Niall JF, et al. Segmental necrotizing glomerulonephritis with antineutrophil antibody: possible arbovirus etiology? BMJ 1982;285:606 – 7. Jennette JC, Falk RJ, Andrassy K, et al. Nomenclature of systemic vasculitides. Proposal of an international consensus conference. Arthritis Rheum 1994;37:187 – 92. Hattori M, Kurayama H, Koitabashi Y for the Japanese Society for Pediatric Nephrology. Antineutrophil cytoplasmic autoantibody-associated glomerulonephritis in children. J Am Soc Nephrol 2001;12:1493 – 500. Valentini RP, Smoyer WE, Sedman AB, et al. Outcome of antineutrophil cytoplasmic autoantibodies-positive glomerulonephritis and vasculitis in children: a single-center expe- rience. J Pediatr 1998;132:325 – 8. Baldree LA, Gaber LW, McKay CP. Anti-neutrophil cytoplasmic autoantibodies in a child with pauci-immune necrotizing and crescentic glomerulonephritis. Pediatr Nephrol 1991;5: 296 – 9. Weening JJ, D’Agati VD, Schwartz MM, et al. The classification of glomerulonephritis in systemic lupus erythematosus revisited. J Am Soc Nephrol 2004;15:241 – 50. Barr RG, Seliger S, Appel GB, et al. Prognosis in proliferative lupus nephritis: the role of socio-economic status and race/ethnicity. Nephrol Dial Transplant 2003;18:2039 – 46. Bogdanovic R, Nikolic V, Pasic S, et al. Lupus nephritis in childhood: a review of 53 patients followed at a single center. Pediatr Nephrol 2004;19:36 – 44. Dooley MA, Hogan S, Jennette C, et al. Cyclophosphamide therapy for lupus nephritis: poor renal survival in black Americans. Glomerular Disease Collaborative Network. Kidney Int 1997;51:1188 – 95. Austin III HA, Boumpas DT, Vaughan EM, et al. Predicting renal outcomes in severe lupus nephritis: contributions of clinical and histologic data. Kidney Int 1994;45:544 – 50. Chan TM, Li FK, Tang CS, et al. Efficacy of mycophenolate mofetil in patients with diffuse proliferative lupus nephritis. Hong Kong–Guangzhou Nephrology Study Group. N Engl J Med 2000;343:1156 – 62. Contreras G, Pardo V, Leclercq B, et al. Sequential therapies for proliferative lupus nephritis. N Engl J Med 2004;350:971 – 80. Dooley MA, Cosio FG, Nachman PH, et al. Mycophenolate mofetil therapy in lupus nephritis: clinical observations. J Am Soc Nephrol 1999;10:833 – 9.