Familial renal amyloidosis (FRA) is a group of hereditary disorders in which misfolded proteins—amyloid—accumulate in the kidneys, causing proteinuria and/or hypertension followed by progressive renal failure. Involvement of other organs (eg, gastrointestinal tract, liver and spleen, heart, skin) varies somewhat depending on the specific genotype.
Susceptibility to FRA is inherited in an autosomal dominant manner (see Presentation/Causes). In nearly all cases, the disease results from mutations in the genes encoding the following four plasma proteins:
However, both penetrance and the clinical phenotype can vary substantially among different families with the same mutation, and even within individual kindreds. Amyloid deposition starts in the first or second decade in some patients, but possibly not until much later in life in others. Consequently, individuals with clinical involvement may present any time from the first decade to old age, although clinical onset most typically occurs in mid-adult life. (See Presentation).
The definitive diagnosis of amyloid accumulation requires histologic confirmation; however, biopsy procedures carry an increased risk of hemorrhage in patients with amyloidosis. (See Workup).
Because organ failure can occur precipitously in organs with extensive amyloid infiltration, treatment of FRA includes scrupulous attention to measures that can reduce the risk of acute kidney injury, as follows:
Nevertheless, kidney failure is inevitable in these patients. Renal replacement with hemodialysis or peritoneal dialysis is feasible until a transplant becomes available. In addition to kidney transplantation, liver transplantation may be indicated; liver transplantation is potentially curative in patients with fibrinogen A alpha-chain FRA and, possibly, in some patients with apolipoprotein AI amyloidosis. (See Treatment).
Amyloidosis is a disorder of protein folding in which normally soluble proteins undergo a conformational change and are deposited in the extracellular space in an abnormal fibrillar form.[1] Accumulation of these fibrils causes progressive disruption of the structure and function of tissues and organs, and the systemic (generalized) forms of amyloidosis are frequently fatal. The conditions that underlie amyloid deposition may be either acquired or hereditary, and at least 20 different proteins can form amyloid fibrils in vivo. See the image below.
View Image | Familial renal amyloidosis. Proposed mechanism for amyloid fibril formation. The drawing depicts a generic amyloid fibril precursor protein (1) in equ.... |
Renal dysfunction is one of the most common presenting features of patients with systemic amyloidosis, and amyloid accumulation is the major pathological finding in approximately 2.5% of all native renal biopsies. Most such patients have either reactive systemic (AA) amyloidosis or monoclonal immunoglobulin light-chain (AL) amyloidosis, but in the few remaining cases, the disease is hereditary.
The syndrome of familial systemic amyloidosis with predominant nephropathy is inherited in an autosomal dominant manner and was first described in a German family by Ostertag in 1932.[2] Research has shown that almost all patients with familial renal amyloidoses (FRA) are heterozygous for mutations in the genes for lysozyme, apolipoprotein AI, apolipoprotein AII, or fibrinogen A alpha-chain and that the amyloid fibrils in this condition are derived from the respective variant proteins. Both penetrance and the clinical phenotype can vary substantially among different families with the same mutation, and even within individual kindreds.
The pathogenesis of amyloid centers around off-pathway folding of the various amyloid fibril precursor proteins. These proteins can exist as two radically different stable structures: the normal soluble form and a highly abnormal fibrillar conformation.
All amyloid fibrils share a common core structure in which the subunit proteins are arranged in a stack of twisted, antiparallel, beta-pleated sheets lying with their long axes perpendicular to the fibril long axis. Proteins that can form amyloid transiently populate partly unfolded intermediate molecular states that expose the beta-sheet domain, enabling them to interact with similar molecules in a highly ordered fashion.
Propagation of the resulting low molecular weight aggregates into mature amyloid fibrils is probably a self-perpetuating process that depends only on a sustained supply of the fibril precursor protein. In some cases, the precursors undergo partial proteolytic cleavage; however, whether this occurs before, during, or after the formation of amyloid fibrils remains unknown.
Studies on hereditary amyloidosis have provided unique and valuable insights into the general pathogenesis of amyloid. Most of the variant proteins associated with hereditary amyloidosis differ from their wild-type counterparts by just a single amino acid substitution, although deletions and insertions also occur (see the Table below).[3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21]
Table. Recognized Genotypes and Their Associated Phenotypes in Familial Renal Amyloidosis
View Table | See Table |
Investigation of the variant amyloidogenic forms of lysozyme has been exceptionally informative because wild-type lysozyme is not associated with amyloidosis and has been thoroughly characterized. The amyloidogenic mutations give rise to amino acid substitutions that subtly destabilize the native fold so that, under physiological conditions, these variants readily visit partly unfolded states, promoting their spontaneous aggregation into amyloid fibrils.
The whole process of lysozyme amyloid fibril formation can be reversed. A soluble functional variant lysozyme has been recovered in vitro from preparations of isolated ex vivo amyloid fibrils that had been denatured and permitted to refold in the normal conformation. Wild-type apolipoprotein AI is inherently moderately amyloidogenic, and small amyloid deposits derived from it occur in aortic atherosclerotic plaques in 20-30% of middle-aged and elderly individuals.
Amyloid deposits in all different forms of the disease, both in humans and in nonhuman animals, contain the nonfibrillar glycoprotein amyloid P component (AP). AP is identical to and derived from the normal circulating plasma protein, serum amyloid P component (SAP), a member of the pentraxin protein family that includes C-reactive protein.
SAP consists of five identical subunits, each with a molecular mass of 25.462 d, which are noncovalently associated in a pentameric disklike ring. The SAP molecule is highly resistant to proteolysis, and, although not itself a proteinase inhibitor, its reversible binding to amyloid fibrils in vitro protects them against proteolysis. In contrast to its normal rapid clearance from the plasma, SAP persists for very prolonged periods within amyloid deposits. The possibility that SAP may contribute to the pathogenesis and/or persistence of amyloid deposits in vivo has been confirmed in studies on SAP knockout mice.[22]
Amyloid deposits accumulate in the extracellular space, progressively disrupting the normal tissue architecture and consequently impairing organ function. Amyloid deposits can also produce space-occupying effects at both microscopic and macroscopic levels. Although amyloid is inert in the sense that it does not stimulate either a local or systemic inflammatory response, some evidence suggests that the deposits exert cytotoxic effects and possibly promote apoptosis.
Strong clinical impressions exist that suggest the rate of accumulation of amyloid has a major bearing on organ function, which can be preserved for very long periods in the presence of an extensive but stable amyloid load. This may reflect adaptation to gradual amyloid accumulation or may relate to toxic properties of newly formed amyloid material.
Prospective studies with serial SAP scintigraphy, a specific and semiquantitative nuclear medicine technique for imaging amyloid deposits (see Workup/Imaging Studies), have confirmed that amyloid deposits are turned over constantly, albeit at a relatively low and variable rate. Therefore, the course of a particular patient's amyloid disease depends on the relative rates of amyloid deposition versus turnover. Amyloid deposits often regress when the supply of the respective fibril precursor protein is reduced, and, under favorable circumstances, this is accompanied by stabilization or recovery of organ function.
Many questions about amyloid deposition remain unanswered. Why only a small number of unrelated proteins form amyloid in vivo remains unclear, and, as yet, little is known about the genetic or environmental factors that determine individual susceptibility to amyloid or factors that govern its anatomical distribution and clinical effects. Hereditary amyloid deposition starts in the first or second decade in some patients, but possibly not until much later in life in other patients. In addition, the mechanism by which amyloid deposits are cleared and why the rate of this varies so substantially among patients are not understood.
No systematic data address the frequency of FRA, but the condition is not as rare as previously thought. The lack of awareness of the condition and the frequent absence of a family history (owing to its variable penetrance) have contributed to substantial underdiagnosis. The incidence of amyloidosis has been estimated at 5 to 13 cases per million population per year; prevalence data are scarce, but one United Kingdom study suggested a rate of about 20 per million inhabitants.[23]
Since the authors introduced routine DNA screening into their investigations of patients with systemic amyloidosis at their facility in the United Kingdom, approximately 5% of patients with presumed AL primary amyloidosis have been diagnosed with hereditary lysozyme, apolipoprotein AI, or fibrinogen A alpha-chain amyloid. The amyloidosis is associated with the fibrinogen A alpha-chain variant Glu526Val in more than 80% of these patients.[24]
The natural history of familial renal amyloidosis is a relentless gradual progression, leading to renal and sometimes other organ failure and, eventually, death. Amyloid deposits can ultimately affect many organ systems, but they may be widespread and very extensive without causing symptoms.
The rate of progression and course of disease are extremely variable. Some patients with clinically overt involvement of multiple organs survive for many years or decades. Overall, the prognosis of patients with FRA is much better than that of those with acquired AA and AL amyloidosis.
Histological localization of amyloid deposits determines overall survival in patients with renal amyloidosis. In a study of 35 patients, the glomerulus was the most common and most severely affected renal compartment. Compared with patients without glomerular amyloid deposits, those with severe glomerular amyloidosis advanced more quickly towards end-stage renal disease and premature death.[25]
Most patients are of northern European ancestry, but fibrinogen A alpha-chain amyloidosis has been reported in Peruvian-Mexican, Korean, and African-American families, and the authors are presently investigating a northern Indian family with uncharacterized FRA.
Gene carriage and the incidence of clinical disease are equal between men and women.
FRA may manifest any time from the first decade to old age but most typically in mid-adult life. The age at presentation, like other clinical features, varies among mutations and even within individual kindreds.
Patients with familial renal amyloidosis (FRA) typically present with proteinuria and/or hypertension followed by progressive renal failure. The latter may evolve extremely slowly, and patients with hereditary apolipoprotein AI and lysozyme amyloidosis may not develop end-stage renal failure for several decades. In contrast to AL amyloidosis, orthostatic hypotension is unusual, probably because autonomic involvement and amyloid cardiomyopathy are rare in FRA.[26, 27]
Many patients give a clear autosomal dominant family history of renal disease, but penetrance is variable. Individuals with the most common form of fibrinogen A alpha-chain amyloidosis, associated with the Glu526Val variant, frequently, or, perhaps even typically, are not aware of any such disease in their family. Patients with FRA who do not give a family history are readily misdiagnosed as having acquired AL amyloidosis.
With variant lysozyme amyloidosis, presentation may involve the following:
The features of hereditary apolipoprotein AI amyloidosis vary significantly with different mutations, as follows:
Hereditary apolipoprotein AII amyloidosis appears to predominantly cause renal disease. Progression to end-stage renal failure occurs, and at least two patients have renal grafts that have functioned for more than a decade. There is one report of a patient with long-standing renal failure who subsequently developed evidence of amyloid cardiomyopathy.
Most patients diagnosed with fibrinogen A alpha-chain Glu526Val amyloidosis present in late middle age with proteinuria or hypertension and progress to end-stage renal failure during the following 5-10 years. Amyloid deposition occurs predominantly in the kidneys and also variably in the spleen, liver, and adrenal glands.[28] Clinically significant neuropathy or cardiac amyloid deposition does not seem to occur in patients with the Glu526Val variant, and liver failure is very rare.
The other three mutations that cause fibrinogen A alpha-chain amyloidosis have been identified in too few families to make generalizations, other than that these mutations are predominantly associated with renal disease.
Clinical features and their association with particular mutations are described in Pathophysiology. Physical examination findings include the following:
Susceptibility to FRA is inherited in an autosomal dominant manner. In nearly all cases, the disease results from mutations in the genes encoding the following four plasma proteins:
In a small number of families, the cause has not yet been determined. Rare cases of renal amyloidosis associated with familial Mediterranean fever have been reported.[29, 30]
Lysozyme is a ubiquitous bacteriolytic enzyme present in both external secretions and in leukocytes. Lysozyme mutations were identified as a cause of familial amyloidosis when, in 1993, amyloid fibrils in two British families were demonstrated to be derived from the lysozyme variants Asp67His and Ile56Thr, respectively. These represent the least common causes of FRA. The authors have identified a polymorphism encoding lysozyme Thr70Asn, which has an allele frequency of 5% in the British population and which has not been shown to be associated with amyloid deposition.
Apolipoprotein AI is a major constituent of high-density lipoprotein (HDL) particles and participates in their central function of reverse cholesterol transport from the periphery to the liver. Approximately half of apolipoprotein AI is synthesized in the liver and half in the small intestine.
Variant forms of apolipoprotein AI are extremely rare in the general population and may be phenotypically silent or may affect lipid metabolism. In 1990, apolipoprotein AI Gly26Arg was identified as a cause of FRA. Since then, 12 other amyloidogenic apolipoprotein AI variants have been discovered. These are mostly other single amino acid substitutions but include deletions and deletion/insertions, not all of which are associated with clinical renal disease (see Pathophysiology). The amyloid fibril subunit protein has comprised the first 90 or so N-terminal residues of apolipoprotein AI in all cases that have been studied, even when the variant residue(s) has been more distal.
In contrast to lysozyme and fibrinogen A alpha-chain types, wild-type apolipoprotein AI is itself weakly amyloidogenic, and the various amyloidogenic variants are likely to render apolipoprotein AI less stable and/or more susceptible to enzymatic cleavage, promoting an abundance of a fibrillogenic N-terminal fragments.
Another potential mechanism could be reduced lipid binding, thereby increasing the amount of free (and therefore relatively less stable) apolipoprotein AI in the plasma.
Apolipoprotein AII is the second major constituent of human HDL particles, accounting for approximately 20% of HDL protein. Like apolipoprotein AI, apolipoprotein AII is synthesized predominantly by the liver and the intestines.
In 2001, apolipoprotein AII stop78Gly was isolated from the amyloid fibrils of a patient who died of renal failure.[31] Since then, an additional three mutations (encoding two protein variants) have been described in association with hereditary renal amyloidosis (see Pathophysiology).
Unlike serum amyloid A protein (another apolipoprotein and the amyloid precursor in AA amyloidosis) or apolipoprotein AI, in apolipoprotein AII amyloidosis, the protein fibrils are not derived from a cleavage fragment of the native precursor but instead consist of the whole protein plus a 21 amino acid extension.
Fibrinogen is a multimeric 340-kd circulating glycoprotein composed of six peptide chains (two each of alpha, beta, and gamma types), all of which are synthesized in the liver. The alpha chains are the largest and are involved in cross-linking fibrin strands. Numerous alpha-chain variants have been recognized that are either silent or are associated with abnormal hemostasis.
Variant fibrinogen A alpha-chain Arg554Leu was first identified as an amyloid fibril protein in 1993. Since then, five other amyloidogenic mutations have been discovered (see the Table). All of these mutations are clustered within the carboxyl terminus of the gene in a relatively small portion of exon 5.
Two of these mutations result in frame shifts that terminate the protein prematurely at codon 548; one is a single nucleotide deletion in the third base of codon 524 and the other is a deletion at codon 522. A single-base transversion, resulting in the substitution of leucine for arginine at codon 554, has been reported in three families of Peruvian-Mexican, African American, and French Caucasian ethnic backgrounds. Residue 554 may be a mutational hot spot because other (nonamyloidogenic) mutations have also been identified at this position.
By far, the most common amyloidogenic variant is fibrinogen A alpha-chain Glu526Val, which has been found in numerous families of Irish, English, German, and Polish origin with FRA.
Genetic information is depicted in the images below.
View Image | Familial renal amyloidosis. An extended kindred with hereditary amyloidosis associated with fibrinogen A alpha-chain Glu526Val; disease penetrance is .... |
View Image | Familial renal amyloidosis. Partial DNA sequence of the gene associated with fibrinogen A alpha-chain Glu526Val in a patient with familial renal amylo.... |
No blood or urine test result is diagnostic of amyloidosis, but lab findings that exclude chronic inflammation or a monoclonal gammopathy in a patient with renal amyloid accumulation support the possibility of familial renal amyloidosis (FRA). Lab tests also have a vital role in evaluating and monitoring amyloidotic organ function.
Protein-to-creatinine (Pr/Cr) ratio in random urine samples was strongly correlated with 24 hour urine protein excretion in a study of 44 patients with amyloidosis, and may be useful for screening for renal involvement. The optimal cut-off point of the Pr/Cr ratio for predicting renal involvement was 715 mg/g, with a sensitivity and specificity of 91.8% and 95.5%, respectively.[32]
Once the creatinine clearance has fallen to less than 20%, progression to end-stage renal disease is almost inevitable, although the rate of decline often does not accord with predictions and may be remarkably slow. On the other hand, step-wise deteriorations in renal function occur quite frequently, even in the absence of any identifiable intercurrent renal insult such as dehydration, infection, or venous thrombosis.
Liver function test results tend to remain normal until the liver has been extensively infiltrated by amyloid, and even marked hepatomegaly may be accompanied by only a modest elevation in serum alkaline phosphatase. Liver function in those with FRA is often well preserved for decades, with elevations of serum bilirubin and transaminase levels occurring at a very late stage. A bilirubin value of just twice the upper limit of normal is associated with a very poor prognosis and incipient liver failure.
Hematological indices and coagulation tend to be unremarkable, although a hyposplenic picture can occur. Occult GI blood loss should be considered in patients with anemia that is not secondary to renal impairment.
Anatomical imaging modalities (eg, plain radiography, computed tomography [CT] scan, magnetic resonance imaging [MRI], ultrasonography) typically yield nonspecific findings in patients with systemic amyloidosis.[33] However, a study by Barreiros et al suggests that ultrasonography can reveal signs of amyloidosis in various organs.[34] In an examination of 30 patients with systemic amyloidosis, including 19 suffering from familial amyloid polyneuropathy, the investigators found the following ultrasonographic indications of amyloidosis:
Radionuclide tracers used for bone scintigraphy occasionally localize in amyloidotic organs.
Serum amyloid P (SAP) component scintigraphy was introduced in 1987 and is a sensitive, specific, and noninvasive method of quantitatively imaging amyloid deposits in vivo.[35] All amyloid fibrils bind the normal plasma protein SAP by virtue of a specific calcium-dependent ligand-protein interaction. In patients with amyloidosis, iodine-123–labeled SAP localizes rapidly and specifically to the amyloid deposits.[22] The technique has a high diagnostic sensitivity and is the only method available for serial monitoring of the progression or regression of amyloid throughout the body.
SAP scintigraphy is eminently suitable as a screening test in patients thought to be at risk for systemic amyloid deposition, including those with known amyloidogenic mutations. However, the technique is not yet available commercially.
Serial SAP scans have shown that accumulation of amyloid tends to be much slower in patients with FRA than in those with acquired AA and AL types, and progression may not be evident, even over the course of a decade. In all types of acquired and hereditary amyloidosis that have been studied, SAP scans have also shown that amyloid deposits are often cleared gradually when the supply of amyloid fibril precursor proteins can be reduced.[36]
Scintigraphic image findings are depicted below.
View Image | Familial renal amyloidosis. Progression of amyloid deposits in a patient with amyloidosis associated with fibrinogen A alpha-chain Glu526Val. These se.... |
View Image | Familial renal amyloidosis. Regression of amyloidosis associated with fibrinogen A alpha-chain Glu526Val following hepatorenal transplantation. The pi.... |
View Image | Familial renal amyloidosis. Regression of amyloidosis associated with apolipoprotein AI Gly26Arg following hepatorenal transplantation. These serial a.... |
Amyloid causes diastolic dysfunction, but contractility remains well preserved until a very late stage. Significant cardiac amyloid deposition is relatively unusual in patients with FRA, especially in patients with lysozyme and fibrinogen types. When it is present, however, it confers a poor prognosis.
Cardiac amyloidosis is best evaluated by a combination of echocardiography, electrocardiography (ECG), and measurement of the N-terminal of the prohormone brain natriuretic peptide (NT-pro BNP). The classic findings with 2-dimensional Doppler echocardiography are as follows:
ECG findings may be normal in patients with substantial cardiac amyloidosis, but reduced voltages, pathological Q waves (ie, pseudoinfarct pattern) in the anterior chest leads, and conduction abnormalities usually signify advanced disease.
DNA analysis is mandatory in all patients with systemic amyloidosis who cannot be confirmed absolutely to have the AA or AL type. Appreciating that the presence of a chronic inflammatory disease or a monoclonal gammopathy may be incidental is important.
Numerous mutations have been identified in most of the genes associated with hereditary amyloidosis, and new variants are being found regularly. Therefore, performing gene sequencing is better than using methods such as restriction fragment length polymorphism analysis, which is directed at particular known mutations.
The results of DNA analysis are not, by themselves, definitive proof of the presence of amyloid or the amyloid fibril type. These findings must be interpreted in light of other clinical and histologic findings.
In cases in which identifying the amyloid fibril type by more conventional means is not possible, isolation of amyloid fibrils from a sample of fresh amyloidotic tissue enables amino acid sequencing of the fibril subunit peptide. This requires technical expertise and is time consuming but can be achieved using very small tissue samples. It is the most definitive method for typing amyloid deposits.
The definitive diagnosis of amyloid accumulation requires histologic confirmation; however, biopsy procedures carry an increased risk of hemorrhage in patients with amyloidosis, and bleeding may be substantial and even life-threatening in 5% of patients who undergo biopsies. This is due to the increased fragility of amyloidotic blood vessels and the reduced elasticity of severely affected organs.
Less-invasive alternatives include fine-needle aspiration of subcutaneous fat and rectal or labial salivary gland biopsy. In experienced hands, these screening biopsies can yield positive results in as many as 80% of cases; however, in routine practice, sensitivity is only approximately 50%. Also, fat aspirates are usually not suitable for immunohistochemical typing.
Many cotton dyes, fluorescent stains such as thioflavine-T, and metachromatic stains have been used, but Congo red staining and its resultant green birefringence when viewed with high-intensity cross-polarized light has the best specificity and is the criterion standard histochemical test for amyloidosis. The stain is unstable and must be freshly prepared at least every 2 months. A section thickness of 5-10 µm and inclusion in every staining run of a positive-control tissue containing modest amounts of amyloid are critical to ensure specificity and quality control.[37]
Other problems in histologically based diagnoses include obtaining adequate tissue samples and an unavoidable element of sampling error. Biopsies cannot reveal the extent or distribution of amyloid accumulation, and failure to demonstrate amyloid in one or even several biopsies does not exclude the diagnosis.
Although many amyloid fibril proteins can be identified immunohistochemically, the demonstration of potentially amyloidogenic proteins in tissues does not, on its own, establish the presence of amyloid. Congo red staining and green birefringence are always required, and immunostaining may then enable the amyloid to be classified.
Antibodies to serum amyloid A protein are commercially available and always stain AA deposits. However, in patients with AL amyloid, the deposits are stainable with standard antisera to kappa or lambda only in approximately half of all cases. This is probably because the light-chain fragment in the fibrils is usually the N-terminal variable domain, which is largely unique for each monoclonal protein.
Immunohistochemistry produces variable results in patients with FRA; the staining is typically weak in patients with fibrinogen A alpha-chain amyloid but is more reliable in patients with lysozyme and apolipoprotein AI types. Including positive tissue and absorption controls in each run is vital for optimal interpretation of the results.
The appearance of amyloid fibrils in tissues under the electron microscope is not always completely specific, and, sometimes, they cannot be identified convincingly. Although electron microscopy should be more sensitive than light microscopy, it is not sufficient by itself to confirm the diagnosis of amyloidosis.
An advance in diagnostic techniques is the use of laser microdissection and mass spectrometry to directly identify the components of the amyloid deposits. A large, single center study has demonstrated that proteomics can be successfully used to type amyloid deposits with more accuracy than conventional immunohistochemistry.[38] However, mass spectrometry–based proteomics is currently available in large referral centers only.[39]
Organs that are extensively infiltrated by amyloid may fail precipitously, with little or no warning and seemingly without provocation, even when results from routine tests of organ function have previously been entirely normal. To reduce the risk of acute organ failure, scrupulous attention must be paid to the following:
Elective surgery and general anesthesia are best avoided in patients with systemic amyloidosis, unless compelling indications are present.
Inexorably progressive organ failure is inevitable, particularly in the case of amyloidotic kidneys, once a certain level of organ dysfunction has occurred. Managing this with hemodialysis or peritoneal dialysis is feasible until a transplant becomes available.
Solid organ transplantation has been used in patients with FRA. Most have been kidney transplants, although liver and heart transplants have also been performed.[28]
Limited worldwide experience suggests that the vast majority of patients with hereditary renal amyloidosis fare remarkably well with transplantation, and despite continued production of the variant amyloidogenic protein, amyloid deposition within renal grafts is usually slow.[40]
Kidney transplantation offers most patients with FRA a much improved quality of life and prolonged survival. Some patients with variant apolipoprotein AI amyloidosis have had renal grafts for longer than 20 years without any reduction in graft function.
Isolated renal transplantation alone has been performed for end-stage renal failure in several patients with fibrinogen alpha-chain amyloidosis and probably remains the treatment of choice in older patients with significant co-morbidity. However, clinically significant renal graft amyloid accumulation occurs within a decade in patients with the most common fibrinogen A alpha-chain variant, Glu526Val, and younger patients benefit from combined liver and renal transplantation.[41]
Few examples have been reported, but renal transplantation may be justified in patients with lysozyme amyloidosis because of its exceptionally slow course and the relative lack of clinical involvement of other organs in patients with this type of FRA.
Liver transplantation has occasionally been performed for liver failure or acute liver rupture in patients with extensive hepatic amyloidosis.[23] However, clinically significant hepatic amyloidosis is always associated with substantial amyloid deposition in other systems, so transplantation for liver failure is palliative unless the production of the respective amyloid fibril precursor protein is reduced.
Orthotopic liver transplantation has been used widely and successfully as a form of surgical gene therapy in patients with transthyretin-related familial amyloid polyneuropathy (FAP) because the variant amyloidogenic protein is produced mainly in the liver.[42]
Successful liver transplantation has now been reported in hundreds of patients with FAP, and, although the peripheral neuropathy usually only stabilizes, autonomic function can improve substantially and the associated visceral amyloid deposits have been shown to regress in many cases.
Fibrinogen is synthesized solely by the liver, and orthotopic hepatic transplantation, therefore, is potentially curative in patients with fibrinogen A alpha-chain amyloidosis.[41] Simultaneous renal transplantation is usually required.[43, 44]
Approximately half of the apolipoprotein AI in the circulation is synthesized in the liver, but among the few patients with hereditary apolipoprotein AI amyloidosis who have undergone liver transplantation, it appears that a reduction in the plasma concentration of variant apolipoprotein AI of 50% is sufficient to facilitate overall regression of systemic amyloid deposits.
Lysozyme is a ubiquitous protein that is produced diffusely within the body, and this type of amyloidosis cannot be ameliorated by liver transplantation.
Two patients with apolipoprotein AI amyloidosis have had successful cardiac transplants. One had cardiac amyloidosis associated with apolipoprotein AI Leu174Ser.
The other presented with severe renal and cardiac involvement resulting from apolipoprotein AI Leu60Arg. This patient was 35 years old and had a combined cardiac and renal transplant. Ten years later, she had normal functional status with no evidence of amyloid deposition in her grafts.
See the list below:
The aims of current medical therapy are to support compromised organ function and to ameliorate symptoms.
Patients are at increased risk of hemorrhage because of increased vascular fragility and/or substantial gastrointestinal amyloid deposits. Unless overwhelming indications for anticoagulation therapy are present, it is best avoided.
No existing treatment specifically results in mobilization and regression of amyloid deposits, but novel drug compounds that inhibit the formation, persistence, and/or effects of amyloid deposits are presently in development.
Clinical Context: Prevents conversion of angiotensin I to angiotensin II, a potent vasoconstrictor, resulting in increased levels of plasma renin and a reduction in aldosterone secretion.
Hypertension is common and can accelerate the decline in renal function. Maintain blood pressure within the lower end of normal range.
Clinical Context: Increases excretion of water by interfering with chloride-binding cotransport system, which, in turn, inhibits sodium and chloride reabsorption in ascending loop of Henle and distal renal tubule. Dose must be individualized to patient. Depending on response, administer at increments of 20-40 mg, no sooner than 6-8 h after previous dose, until desired diuresis occurs.
Often help treat symptomatic peripheral edema resulting from nephrotic syndrome.
Clinical Context: Decreases gastric acid secretion by inhibiting the parietal cell H+/K+ -ATP pump.
Acute GI bleeding or perforation is the cause of death in a large proportion of patients with lysozyme amyloidosis, and long-term prophylactic treatment with a proton pump inhibitor is advisable.
Clinical Context: Inhibits histamine stimulation of the H2 receptor in gastric parietal cells, which, in turn, reduces gastric acid secretion, gastric volume, and hydrogen concentrations.
Clinical Context: Inhibits histamine at H2 receptors of gastric parietal cells, which results in reduced gastric acid secretion, gastric volume, and hydrogen concentrations.
Reversible competitive blockers of histamine at the H2 receptors, particularly those in the gastric parietal cells, where they inhibit acid secretion. The H2 antagonists are highly selective, do not affect the H1 receptors, and are not anticholinergic agents.
Clinical Context: A dopamine antagonist that stimulates gastric emptying and small intestinal transit.
Gastric emptying may be delayed, and some patients respond quite well to prokinetic agents or antiemetics.
Ensure regular follow-up care with scrupulous attention to control of blood pressure.
Genetic screening is possible for family members. Adequate counseling is a necessity because the age of onset and penetrance are highly variable and no specific treatment is available.
Prenatal diagnosis is technically possible but is of uncertain value because many individuals with these particular gene mutations have a normal life expectancy.
Acute kidney injury and chronic kidney disease can occur in the following forms of familial renal amyloidosis (FRA):
Acute and chronic liver failure can occur in the following forms of FRA:
The following complications can occur in these forms of FRA:
Many patients with FRA survive until the seventh decade or older, and most patients survive for at least 10 years after diagnosis. Life expectancy has increased substantially since kidney and liver transplantations have been introduced as treatments for these diseases. Liver transplantation is potentially curative in patients with fibrinogen A alpha-chain FRA and, possibly, in some patients with apolipoprotein AI amyloidosis.
Patient education should include the following:
Familial renal amyloidosis. Proposed mechanism for amyloid fibril formation. The drawing depicts a generic amyloid fibril precursor protein (1) in equilibrium with a partially unfolded, molten, globulelike form of the protein (2) and its completely denatured state (3). Autoaggregation through the beta domains initiates fibril formation (4), providing a template for ongoing deposition of precursor proteins and for the development of the stable, mainly beta-sheet, core structure of the fibril (5). The amyloidogenic precursor proteins in patients with familial renal amyloidosis are thought to be less stable than their wild-type counterparts, causing them to populate intermediate, molten, globulelike states more readily.
Familial renal amyloidosis. Progression of amyloid deposits in a patient with amyloidosis associated with fibrinogen A alpha-chain Glu526Val. These serial posterior, whole-body, scintigraphic images were obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a 48-year-old man with hereditary amyloidosis associated with fibrinogen A alpha-chain Glu526Val in whom asymptomatic proteinuria had been identified. Both parents were alive and well and older than age 80 years. The scan at diagnosis (left) showed modest abnormal uptake into renal amyloid deposits, which increased at follow-up 3 years later (right). The remainder of the image represents a normal distribution of tracer throughout the blood pool.
Familial renal amyloidosis. Regression of amyloidosis associated with fibrinogen A alpha-chain Glu526Val following hepatorenal transplantation. The pictures are serial anterior, whole-body, scintigraphic images obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a patient with amyloidosis associated with fibrinogen A alpha-chain Glu526Val. Prior to hepatorenal transplantation (left), heavy amyloid deposition was present in an enlarged liver and spleen. No amyloid deposits were identified in a follow-up study obtained 42 months after hepatorenal transplantation (right); only a normal distribution of tracer is present throughout the blood pool.
Familial renal amyloidosis. Regression of amyloidosis associated with apolipoprotein AI Gly26Arg following hepatorenal transplantation. These serial anterior, whole-body, scintigraphic images were obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a patient with hereditary amyloidosis associated with apolipoprotein AI Gly26Arg. Prior to hepatorenal transplantation (left), heavy amyloid deposition was present in the liver, obscuring the kidneys. Two years after combined hepatorenal transplantation (right), a follow-up scan was normal, showing tracer distributed evenly throughout the background blood pool, including the transplanted organs. Splenic amyloid deposits that were evident initially in posterior scans had regressed at follow-up.
Familial renal amyloidosis. Proposed mechanism for amyloid fibril formation. The drawing depicts a generic amyloid fibril precursor protein (1) in equilibrium with a partially unfolded, molten, globulelike form of the protein (2) and its completely denatured state (3). Autoaggregation through the beta domains initiates fibril formation (4), providing a template for ongoing deposition of precursor proteins and for the development of the stable, mainly beta-sheet, core structure of the fibril (5). The amyloidogenic precursor proteins in patients with familial renal amyloidosis are thought to be less stable than their wild-type counterparts, causing them to populate intermediate, molten, globulelike states more readily.
Familial renal amyloidosis. Progression of amyloid deposits in a patient with amyloidosis associated with fibrinogen A alpha-chain Glu526Val. These serial posterior, whole-body, scintigraphic images were obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a 48-year-old man with hereditary amyloidosis associated with fibrinogen A alpha-chain Glu526Val in whom asymptomatic proteinuria had been identified. Both parents were alive and well and older than age 80 years. The scan at diagnosis (left) showed modest abnormal uptake into renal amyloid deposits, which increased at follow-up 3 years later (right). The remainder of the image represents a normal distribution of tracer throughout the blood pool.
Familial renal amyloidosis. Regression of amyloidosis associated with fibrinogen A alpha-chain Glu526Val following hepatorenal transplantation. The pictures are serial anterior, whole-body, scintigraphic images obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a patient with amyloidosis associated with fibrinogen A alpha-chain Glu526Val. Prior to hepatorenal transplantation (left), heavy amyloid deposition was present in an enlarged liver and spleen. No amyloid deposits were identified in a follow-up study obtained 42 months after hepatorenal transplantation (right); only a normal distribution of tracer is present throughout the blood pool.
Familial renal amyloidosis. Regression of amyloidosis associated with apolipoprotein AI Gly26Arg following hepatorenal transplantation. These serial anterior, whole-body, scintigraphic images were obtained following intravenous injection of iodine-123 (123I)–labeled human serum amyloid P component into a patient with hereditary amyloidosis associated with apolipoprotein AI Gly26Arg. Prior to hepatorenal transplantation (left), heavy amyloid deposition was present in the liver, obscuring the kidneys. Two years after combined hepatorenal transplantation (right), a follow-up scan was normal, showing tracer distributed evenly throughout the background blood pool, including the transplanted organs. Splenic amyloid deposits that were evident initially in posterior scans had regressed at follow-up.
Amyloid Fibril Precursor Protein Organs/Tissues Predominantly Affected by Amyloid and Common Clinical Features Ethnic Origin of Affected Kindreds Lysozyme Ile56Thr Renal - Proteinuria and renal failure
Skin - Petechial rashes
Liver and spleen - Organomegaly (usually well-preserved function)2 British families
(possibly related)Lysozyme Asp67His Renal - Proteinuria and renal failure
GI tract - Bleeding and perforation
Liver and spleen - Organomegaly and hepatic hemorrhage
Salivary glands – Sicca syndromeSingle British family Lysozyme Try64Arg Renal - Proteinuria and renal failure
GI tract - Bleeding and perforation
Salivary glands – Sicca syndromeSingle French family Lysozyme Trp82Arg Renal - Proteinuria and renal failure Single Chinese family Apolipoprotein AI
wild typeAmyloid deposits in human aortic atherosclerotic plaques 20-30% of elderly individuals at autopsy Apolipoprotein AI
Gly26ArgRenal - Proteinuria and renal failure
Gastric mucosa - Peptic ulcers
Peripheral nerves - Progressive neuropathy
Liver and spleen - Organomegaly (usually well-preserved function)Multiple families
(mostly of northern European extraction)Apolipoprotein AI
Trp50ArgRenal - Proteinuria and renal failure
Liver and spleen - Organomegaly and liver failureSingle Ashkenazi family Apolipoprotein AI
Leu60ArgRenal - Proteinuria and renal failure
Liver and spleen - Organomegaly (usually well-preserved function)
Cardiac (rarely) - Heart failureBritish and
Irish kindredsApolipoprotein AI
deletion 60-71
insertion 60-61Liver - Liver failure Single Spanish family Apolipoprotein AI
Leu64ProRenal - Proteinuria and renal failure
Liver and spleen - OrganomegalySingle Canadian-Italian family Apolipoprotein AI
deletion 70-72Renal - Proteinuria and renal failure
Liver and spleen - Organomegaly (usually well-preserved function)
Retina - Central scotomaSingle family of British origin Apolipoprotein AI
Leu75ProRenal - Proteinuria and
renal failure
Liver and spleen - OrganomegalyItaly – Variable penetrance Apolipoprotein AI
Leu90ProCardiac - Heart failure
Larynx - Dysphonia
Skin – Infiltrated yellowish plaquesSingle French family Apolipoprotein AI
deletion Lys107Aortic intima - Aggressive early-onset ischemic heart disease Single Swedish patient at autopsy Apolipoprotein AI
Arg173ProCardiac - Heart failure
Larynx - Dysphonia
Skin - Acanthosis nigricans-like plaquesBritish and American families Apolipoprotein AI
Leu174SerCardiac - Heart failure Single Italian family Apolipoprotein AI
Ala175ProLarynx - Dysphonia
Testicular - InfertilitySingle British family Apolipoprotein AI Leu178His Cardiac - Heart failure
Larynx – Dysphonia
Skin - Infiltrated plaques
Peripheral nerves – NeuropathySingle French family Apolipoprotein AII
Stop78GlyRenal - Proteinuria and renal failure American family Apolipoprotein AIIStop78Ser Renal - Proteinuria and renal failure American family Apolipoprotein AIIStop78Arg Renal - Proteinuria and renal failure Russian family, Spanish family(different nucleotide substitutions in the two kindreds) Fibrinogen A alpha-chain Arg554Leu Renal - Proteinuria and renal failure Peruvian,
African American and
French familiesFibrinogen A alpha-chain
frame shift at codon 522Renal - Proteinuria and renal failure Single French family Fibrinogen A alpha-chain
frame shift at codon 524Renal - Proteinuria and renal failure Single American family Fibrinogen A alpha-chain Glu526Val Renal - Proteinuria and renal failure
Late-onset liver (rarely) - Organomegaly and liver failureMultiple families
(northern European extraction,
variable penetrance)Fibrinogen A alpha-chain Gly540Val Renal - Proteinuria and renal failure Single German family Fibrinogen A alpha-chain Indel 517-522 Renal - Proteinuria and renal failure Single Korean child