Membranous nephritis: Difference between revisions

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| width=100px; bgcolor="#d9ff54" |'''Degree of Nephrotic-Range Proteinuria (g/24hrs)'''||bgcolor="#d9ff54"|'''Patients With Spontaneous Remission (%)<ref name="pmid20110379">{{cite journal| author=Polanco N, Gutiérrez E, Covarsí A, Ariza F, Carreño A, Vigil A et al.| title=Spontaneous remission of nephrotic syndrome in idiopathic membranous nephropathy. | journal=J Am Soc Nephrol | year= 2010 | volume= 21 | issue= 4 | pages= 697-704 | pmid=20110379 | doi=10.1681/ASN.2009080861 | pmc=PMC2844306 | url=http://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=20110379 }} </ref>'''
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Revision as of 01:47, 9 November 2013

Template:DiseaseDisorder infobox

Overview

Membranous nephropathy (MN) or membranous glomerulonephritis (MGN) is a common glomerulonephritis that usually presents with nephrotic-range proteinuria, edema, and hypertension. MN is generally classified as primary (idiopathic) or secondary to other systemic disease, such as infections, malignancies, vasculitides etc. Primary MN has been recently associated with the presence of a newly discovered phospholipase A2 receptor (PLA2R) nephrotigenic antigen on the membrane surface of glomerular podocytes and anti-PLA2R antibodies. Kidney biopsy remains the gold standard for the diagnosis of MN, showing subepithelial deposits with capillary wall thickening and IgG deposition under immunofluorescence. While MN is widely considered a chronic condition with a waxing and waning course, it is usually self-limited in the majority of the cases. Heavy proteinuria, a significant marker of prognosis, indicates the need for intervention.

Historical Perspective

The term “membranous nephropathy” was first coined by Elexious T. Bell[1], a pathologist, in 1946 to describe a specific disease entity characterized by gradual-onset proteinuria and edema under Ellis type II glomerulonephritis, a classification by Arthur Ellis based on clinical and histopathological findings.[1] In 1957, David Jones used acid-silver methenamine, also known as Jones stain, to demonstrate that membranous nephropathy must be considered a unique glomerulonephritis due to the characteristic presence of capillary wall thickening and disruption of basement membrane.[2]

In 1959, Movat and McGregor used electron microscopy to identify subepithelial deposits in membranous nephropathy[3], based on earlier findings by Coons and Kaplan in 1950[4], Farquhar[5], and Mellors[6] in 1957.

It was not until 2009 when Beck and colleagues[7] discovered that antibodies against the nephritogenic phospholipase A2 receptor (PLA2R) is associated with the pathogenesis of the disease.

Epidemiology and demographics

Membranous nephropathy or membranous glomerulonephritis (MGN) has always been considered the most common glomerulonephritis associated with nephrotic syndrome, defined as severe proteinuria > 3.5 g/d, accounting for approximately 36% of cases.[8] Only recently, new data is suggesting that focal segmental Glomerulosclerosis (FSGS) may have surpassed MN as the leading cause of unexplained nephrotic syndrome.[8]

In general, MGN may be a disease of any age, any gender, and any ethnicity. However, the peak incidence of primary MN is between 40 and 50 years of age[9]; and it is very rarely seen in children. There is a slight male predominance to the disease and it is thought to be more common among Caucasian.[9] In 1996, Korbet and colleagues showed that among 340 patients with primary glomerulonephritis presenting with nephrotic syndrome over 20 years, MGN accounts for 24% of cases in African-American patients vs. 36% of cases in Caucasian patients.[10]

MGN is considered very rare in the pediatric population. Only 1-4% of all MGN is among children aged 1-12 years, and MGN comprises only 1.5% of all cases of nephrotic syndromes among children.[11][12] However, the incidence of MGN increases to 22% among patients aged 13-19 years.[12][13]

Secondary MGN, however, may have different age and geographic distributions.[14][15][16][17][18]

Among adult patients, most cases of MGN are idiopathic.[19] Only 20-30% of cases are due to secondary causes, such as infections, systemic illnesses, cancers, and medications in adults. (18235148). Secondary causes are in fact much more common in the pediatric age groups, reaching up to 35-75% of all cases of MGN.[20][11]

The majority of the patients present with mild proteinuria; but 60% of those eventually progress into nephrotic-range proteinuria within 1-2 years.

Pathophysiology

Early description of the pathophysiology of the membranous nephropathy noted that the disease might be due to an auto-antibody production against an antigen on podocytes surfaces.[1][21][22] In 2009, Beck and colleagues[7] discovered that M-type phospholipase A2 receptor (PLA2R) protein as a nephritogenic antigen. It is currently believed that anti-PLA2R is present in approximately 80% of patients with primary membranous nephropathy[7][23][24][25][26] and to a much lesser extent in patients with secondary membranous nephropathy in patients, most notably in patients with hepatitis B and malignancies.[26] PLA2R1 is a 185-KDa glycoprotein expressed on the podocyte membrane surface.[7][27] Physiologically, its role has not been confirmed, but is presumed to be involved in the aging of the cell through the p53 pathway. It contains several characteristic domains[27]:

  • Extracellular domain: Long domains with cysteine-rich head and a nephritogenic epitope at a methionine-rich terminal
  • Fibronectin type II-like repeat domains
  • Repeated carbohydrate-recognition domains
  • Membrane-spanning domains


Intracellular domainsThe nephritogenic epitope in the extracellular domain is destroyed when the cysteine-cysteine disulfide bridges are disrupted.[7] Control of immune response by anti-PLA2R antibodies is controlled genetically by PLA2R1 gene locus at chromosome 2 and HLA-DQA1 and DQB1 on chromosome 6.[28] Peptides from PLA2R1 bind HLA-DQA1-expressing-antigen-presenting cells activate T cells and subsequently cause the production of antibodies, such as IgG4, by Th2 cytokine activation.[29][30][31] that contribute to clinical manifestations, such as proteinuria. The latter finding has been associated with unique molecular findings, such as formation of membrane attack complex (C5b-C9) and activation T-cell activation (CD8+).[29][30]


Presence of immunoglobulin subclass may have important pathological effects.

  • IgG4: Associated with primary membranous nephropathy. It is presumed to have a “protective” effect when IgG1 is present because it acts against the formation of immune complexes.[22][32]
  • IgG1, IgG2, and IgG3: Associated with secondary membranous nephropathy. Their role seems to be pathogenic.[22][32]


The presence of anti-PLA2R has been correlated with clinical manifestations, prognosis, and recurrence of disease in membranous nephropathy.[33][34]

Several hypotheses have been postulated as to why a small number of patients with primary membranous nephropathy and the majority of those with secondary membranous nephropathy do not have detectable anti-PLA2R antibodies.[22] These factors are summarized as follows[22]:

  • Poorly sensitive assays used for detection
  • Heterogeneous conformation of PLA2R epitope
  • Disappearance of antibodies spontaneously or due to treatment
  • Involvement of other nephritogenic antigens


Other antigens have been implicated in the disease and may have a role in the pathogenesis of membranous nephropathy. However, these antigens still require further validation.[22][23][24][35][36][37][38][39][40][41]:

  • Neutral endopeptidase
  • Superoxide dismutase
  • Aldose reductase
  • Alpha-enolase
  • Cationic serum albumin
  • Renal tubular antigens (megalin)

Causes

Primary Membranous Nephropathy

Most cases of MGN are primary. The cause is thus unknown and they are designated as “idiopathic”.


Secondary Membranous Nephropathy

Less commonly in adults, MGN may be associated with secondary etiologies. According to the National Kidney Foundation (NKF) Kidney Disease – Improving Global Outcomes (KDIGO) published in 2012, the list of secondary causes of MGN is listed as shown below.

The prevalence of secondary MGN is more common among children, comprising up to 35-75% of all MGN cases in this age group. The most common secondary etiology to pediatric MGN is hepatitis B virus.[11]

Autoimmune Etiologies

  • Systemic lupus erythematosus
  • Rheumatoid arthritis
  • Mixed connective tissue disease
  • Dermatomyositis
  • Ankylosing spondylitis
  • Systemic sclerosis
  • Myasthenia gravis
  • Bullous pemphigoid
  • Autoimmune thyroid disease
  • Sjogren’s syndrome
  • Temporal arteritis
  • Crohn’s disease
  • Graft-vs-host disease

Infectious Etiologies

  • Hepatitis B
  • Hepatitis C
  • HIV
  • Malaria
  • EBV
  • Schistosomiasis
  • Filariasis
  • Syphilis
  • Enterococcal endocarditis
  • Hydatid disease
  • Leprosy

Tumors

  • Lung cancer
  • Colon cancer
  • Breast cancer
  • Gastric cancer
  • Ovarian cancer
  • Prostate cancer
  • Orophayngeal or esophageal cancer
  • Hodgkin's lymphoma
  • Non-Hodgkin's lymphoma
  • Chronic lymphocytic leukemia
  • Mesothelioma
  • Melanoma
  • Wilm's tumor
  • Hepatic adenoma
  • Angiolymphatic hyperplasia
  • Schwannoma
  • Neuroblastoma
  • Adrenal ganglioneuroma

Medications

  • Penicillamine
  • Bucillamine
  • Captopril
  • Probenicid
  • Trimethadione
  • NSAID
  • Cyclooxygenase 2 inhibitors
  • Clopidogrel
  • Lithium

Other Toxins

  • Gold salts
  • Mercury
  • Formaldehyde
  • Hydrocarbon

Other Etiologies

  • Diabetes mellitus
  • Sarcoidosis
  • Sickle cell disease
  • Polycystic kidney disease
  • Alpha-1-antitryprsin deficiency
  • Weber-Christian disease
  • Primary biliary cirrhosis
  • Systemic mastocytosis
  • Guillain-Barre syndrome
  • Urticarial vasculitis
  • Hemolytic uremic syndrome
  • Dermatitis herpetiformis
  • Myelodysplasia

Classification

The classification of MGN is based on the presence of electron-dense deposits on electron microscopy.[11][42] This staging has been first described by Ehrenreich and Churg in 1963.

Stage Features
Stage I
  • Small sparsely distributed electron-dense subepithelial deposits
  • No thickening of the glomerular basement membrane (GBM)
Stage II
  • Extensive subepithelial deposits
  • Formation of GBM spikes between deposits (silver-staining segments of basement membrane between dense deposits)
  • Thickening of GBM
  • Deposits are not completely surrounded by basement membrane
Stage III
  • Incorporation of dense deposits in the basement membrane
  • Deposits completely surrounded by basement membrane
Stage IV
  • Dense Deposits incorporated in the GBM
  • Irregular marked thickening and dissolution of GBM

Differentiating membranous nephropathy from other diseases

Other common forms of glomerulonephritis that present with nephrotic syndrome are common differential diagnoses of membranous nephropathy.

  • Minimal change disease
  • Focal segmental Glomerulosclerosis
  • Membranoproliferative glomerulonephritis

Diagnosis

Kidney biopsy is the gold standard for the diagnosis of MGN. On light microscopy, kidney biopsy typically shows subepithelial despoits with capillary wall thickening and normal cellularity. Immunofluorescence shows IgG and C3 deposits along capillary walls. Electron microscopy shows exclusively subepithelial deposits between podocyte foot processes.

Subtype of IgG present on immunofluorescence may be helpful in differentiating idiopathic vs. secondary causes of MGN. In primary idiopathic MGN, the IgG4 subtype of IgG is most commonly seen whereas IgG1, 2, and 3 are more commonly seen in secondary MGN.[43][44][11]

Furthermore, the location of the deposits may also provide clues on the diagnosis. While deposits in primary MGN are exclusively seen in the subepithelial region, deposits in secondary MGN may involve subepithelial and more likely subendothelial regions of the capillary wall.[44][11]

A repeat biopsy may only be necessary if deteriorating kidney function ensues with doubling of serum creatinine occurs over 1-2 months while proteinuria remains below 15 g/d.

Prognosis

The degree of presenting proteinuria is considered the most important prognostic factor. Quantification of proteinuria is of major prognostic significance because proteinuria seems to have a “dose-dependent” effect on prognosis and on rates of spontaneous remission. As such, mild non-nephrotic proteinuria is associated with increased chances for spontaneous remission.[45] The rate of remssion may be delayed to several years, especially when proteinuria becomes in the sub-nephrotic range; the rate of proteinuria reduction might be very slow and occur over several years before completely normal renal function is restored.[43] On the other hand, it is unlikely that patients with heavy proteinuria to experience spontaneous remission.[45]

Degree of Nephrotic-Range Proteinuria (g/24hrs) Patients With Spontaneous Remission (%)[45]
3.5 - 8

37.1

8 - 12

26

> 12

22

Adapted from Polanco N, Gutierrez E, Covarsi A, et al. Spontaneous remission of nephropatic syndrome in idiopathic membranous nephropathy. J Am Soc Nephrol. 2010; 21(4):697-704

Furthermore, the decrease in proteinuria from baseline during the first 6-12 months, as shown by Polanco et al. in 2010, to more than 50% has been shown to be of favorable outcome in patients with idiopathic MGN.[45][46] Age and gender have also been shown to be consistently associated with prognosis. Age < 50 years and female gender seem to be associated with spontaneous remission.

As such, the 3 main elements that favor good prognosis are as follows:

Ever since the description of PLA2R in 2009 19571279, serum levels of anti-PLA2R antibodies have been implicated in clinical manifestations, prognosis, and recurrence of disease in patients with membranous nephropathy.[33][22][34] Decreasing levels also seem to correlate with resolution of disease.[34]

Interestingly, histopathological findings of MGN does not seem to be highly emphasized in the literature as a prognostic factor as seen in other glomerulonephritides, despite presence of low-quality evidence to support such hypothesis. However, large extent of fibrosis and sclerosis seen on pathology and specific heterogeneous configurations (vs. synchronous deposits) of immune deposits have been associated with poorer prognosis.[48][49][50]


Other less significant factors that have been shown to be associated with spontaneous remission:

  • Renal insufficiency > 1.5 mg/dL[51]
  • Presence of urinary alpha-1-microglobulin or beta-2-microglobulin[51][52][53]
  • Presence of urinary IgG and IgM[52][53]
  • Presence of hypertension[54]
  • Histologic evidence of interstitial fibrosis, tubular atrophy, and segmental glomerular sclerosis.[55]
  • Persistently elevated urinary C5b-9[56]


Treatment may significantly alter prognosis in MGN; where use of ACE-inhibitors or ARB and the consequent reduction in proteinuria are key to improve prognosis and renal outcomes[57]

References

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