Tatiana Prokaeva

Cardiac amyloidosis in African Americans: Comparison of clinical and laboratory features of transthyretin V122I amyloidosis and immunoglobulin light chain amyloidosis

BACKGROUND Transthyretin (TTR) mutations known to cause cardiac amyloidosis include V122I, found almost exclusively in African Americans at a prevalence of 3-3.9%. This retrospective study describes TTR V122I-associated cardiac amyloid disease (ATTR) in a major amyloid referral clinic population. METHODS Self-identified African Americans with amyloidosis (n = 156) were screened for TTR V122I by serum isoelectric focusing; mutant TTR was confirmed by DNA sequencing or mass spectrometry. Cardiac findings in ATTR V122I and immunoglobulin light chain (AL) amyloidoses were compared. RESULTS TTR V122I was identified in 36/156 (23.1%) of evaluated patients and included 5 homozygotes; the allele frequency was 0.013. One compound heterozygote (F44L/V122I) and 4 patients who had AL and the mutant TTR allele were characterized. In patients negative for V122I, AL was the most frequent diagnosis (86/120). Cardiomyopathy was present in 100% of patients with ATTR and 84% of patients with AL (P = .01). In patients with dominant cardiac involvement, better survival occurred in ATTR (n = 30) compared to AL (n = 31), (27 vs 5 months, P < .01) although the mean age in ATTR was higher (70.3 vs 56.2 years, P < .01). Congestive heart failure symptoms and electrocardiographic findings were similar in ATTR and AL, but significant differences in echocardiographic measurements were observed. CONCLUSIONS ATTR V122I and AL are equally prevalent as the cause of cardiomyopathy in African Americans referred for a diagnosis of amyloidosis. Available therapy for AL underscores the need for early and accurate determination of amyloid type.

Amyloidogenic and Associated Proteins in Systemic Amyloidosis Proteome of Adipose Tissue

In systemic amyloidoses, widespread deposition of protein as amyloid causes severe organ dysfunction. It is necessary to discriminate among the different forms of amyloid to design an appropriate therapeutic strategy. We developed a proteomics methodology utilizing two-dimensional polyacrylamide gel electrophoresis followed by matrix-assisted laser desorption/ionization mass spectrometry and peptide mass fingerprinting to directly characterize amyloid deposits in abdominal subcutaneous fat obtained by fine needle aspiration from patients diagnosed as having amyloidoses typed as immunoglobulin light chain or transthyretin. Striking differences in the two-dimensional gel proteomes of adipose tissue were observed between controls and patients and between the two types of patients with distinct, additional spots present in the patient specimens that could be assigned as the amyloidogenic proteins in full-length and truncated forms. In patients heterozygotic for transthyretin mutations, wild-type peptides and peptides containing amyloidogenic transthyretin variants were isolated in roughly equal amounts from the same protein spots, indicative of incorporation of both species into the deposits. Furthermore novel spots unrelated to the amyloidogenic proteins appeared in patient samples; some of these were identified as isoforms of serum amyloid P and apolipoprotein E, proteins that have been described previously to be associated with amyloid deposits. Finally changes in the normal expression pattern of resident adipose proteins, such as down-regulation of αB-crystallin, peroxiredoxin 6, and aldo-keto reductase I, were observed in apparent association with the presence of amyloid, although their levels did not strictly correlate with the grade of amyloid deposition. This proteomics approach not only provides a way to detect and unambiguously type the deposits in abdominal subcutaneous fat aspirates from patients with amyloidoses but it may also have the capability to generate new insights into the mechanism of the diseases by identifying novel proteins or protein post-translational modifications associated with amyloid infiltration.

Clinical and molecular characteristics of patients with non-amyloid light chain deposition disorders, and outcome following treatment with high-dose melphalan and autologous stem cell transplantation

Light chain deposition disease (LCDD) is caused by a clonal plasma cell disorder in which fragments of monoclonal immunoglobulin light chains form non-fibrillary deposits in various tissues resulting in organ dysfunction. Crystal storing histiocytosis (CSH) is another light chain deposition disorder in which monoclonal light chains form intracytoplasmic crystals. Both are uncommon diseases for which there is limited treatment experience. Between 2003 and 2005, five patients with LCDD and one with CSH were treated at Boston University Medical Center with high-dose melphalan and autologous peripheral blood stem cell transplantation (HDM/SCT). Five of the six patients had predominantly renal involvement, and one patient with LCDD had biopsy-proven deposits in the myocardium. Molecular characterization revealed that the pathologic light chains were κ in four of the six patients, and sequence analysis revealed unusual germline donor genes and high rates of amino-acid substitutions. One light chain sequence encoded a new potential N-linked glycosylation site, and another showed evidence of antigen selection. All patients are alive and five of the six patients are in complete hematologic remission at a median follow-up of 12 months (range 4–29 months) after HDM/SCT. In our experience, HDM/SCT is a feasible and effective treatment approach for these disorders.

Identification of S-sulfonation and S-thiolation of a novel transthyretin Phe33Cys variant from a patient diagnosed with familial transthyretin amyloidosis

Familial transthyretin amyloidosis (ATTR) is an autosomal dominant disorder associated with a variant form of the plasma carrier protein transthyretin (TTR). Amyloid fibrils consisting of variant TTR, wild‐type TTR, and TTR fragments deposit in tissues and organs. The diagnosis of ATTR relies on the identification of pathologic TTR variants in plasma of symptomatic individuals who have biopsy proven amyloid disease. Previously, we have developed a mass spectrometry‐based approach, in combination with direct DNA sequence analysis, to fully identify TTR variants. Our methodology uses immunoprecipitation to isolate TTR from serum, and electrospray ionization and matrix‐assisted laser desorption/ionization mass spectrometry (MS) peptide mapping to identify TTR variants and posttranslational modifications. Unambiguous identification of the amino acid substitution is performed using tandem MS (MS/MS) analysis and confirmed by direct DNA sequence analysis. The MS and MS/MS analyses also yield information about posttranslational modifications. Using this approach, we have recently identified a novel pathologic TTR variant. This variant has an amino acid substitution (Phe → Cys) at position 33. In addition, like the Cys10 present in the wild type and in this variant, the Cys33 residue was both S‐sulfonated and S‐thiolated (conjugated to cysteine, cysteinylglycine, and glutathione). These adducts may play a role in the TTR fibrillogenesis.

AL-Base: a visual platform analysis tool for the study of amyloidogenic immunoglobulin light chain sequences

AL-Base, a curated database of human immunoglobulin (Ig) light chain (LC) sequences derived from patients with AL amyloidosis and controls, is described, along with a collection of analytical and graphic tools designed to facilitate their analysis. AL-Base is designed to compile and analyse amyloidogenic Ig LC sequences and to compare their predicted protein sequence and structure to non-amyloidogenic LC sequences. Currently, the database contains over 3000 de-identified LC nucleotide and amino acid sequences, of which 433 encode monoclonal proteins that were reported to form fibrillar deposits in AL patients. Each sequence is categorised according to germline gene usage, clinical status and sample source. Currently, tools are available to search for sequences by various criteria, to analyse the biochemical properties of the predicted amino acids at each position and to display the results in a graphical fashion. The likelihood that each sequence has evolved through somatic hypermutation can be predicted using an automated binomial or multinomial distribution model. AL-Base is available to the scientific community for research purposes.

Identification of a novel transthyretin Thr59Lys/Arg104His. A case of compound heterozygosity in a Chinese patient diagnosed with familial transthyretin amyloidosis.

Transthyretin (TTR) is a 127-amino acid residue protein synthesized mainly in the liver and in several minor sites, including the choroid plexus and the eye. in plasma, TTR circulates as a homotetramer and transports the hormone thyroxine and the retinol-binding protein-vitamin A complex. It is hypothesized that amino acid substitutions in TTR destabilize the tetramer by causing each subunit to form intermediates that may self-associate into amyloid fibrils. Deposition of wild type TTR, its variants and/or fragments as amyloid fibrils in tissues and organs is associated with familial transthyretin amyloidosis (A TTR). Reported herein is the characterization of a novel TTR Thr59Lys/Arg104His in a patient of Chinese ancestry, who was diagnosed with A TTR. The two variant proteins and the double gene mutations in this compound heterozygous case were detected and identified using a multifaceted approach consisting of isoelectric focusing, electrospray ionization mass spectrometry (MS), matrix-assisted laser desorption/ionization time-of-flight MS in combination with enzymatic digestion, and direct DNA sequence analysis. Previous studies have shown that the TTR Arg104His variant is non-pathologic. It appeared to provide a protective effect in another compound heterozygous case (TTR VaBOMet/Arg104His). However. the TTR Arg104His variant when presented with the TTR Thr59Lys variant did not seem to have any protective role.

A new transthyretin variant (Glu61Gly) associated with cardiomyopathy

We report the identification of a new transthyretin (TTR) gene mutation and variant protein, Glu61Gly, in a 55-year-old man with progressive cardiomyopathy, mild peripheral neuropathy and bilateral carpal tunnel syndrome. A diagnosis of TTR-associated familial amyloidosis (ATTR) was considered after an endomyocardial biopsy revealed amyloid deposits in the heart of a patient who had no family history of amyloidosis and no evidence of a plasma cell dyscrasia. Serum screening for a TTR variant by isoelectric focusing (IEF) was positive and prompted further studies to identify the genetic abnormality and to characterize the amyloidogenic protein. Direct DNA sequence analysis of all four coding regions in the TTR gene demonstrated heterozygosity in exon 3. Near equal amounts of guanine (G) and adenine (A) were observed at the second base position of codon 61. The wild-type (GAG) and mutated (GGG) sequences found in codon 61 correspond to glutamic acid (Glu) and glycine (Gly) residues, amino acids which differ in mass by −72 Da. Mass spectrometric analyses of TTR immunoprecipitated from serum showed the presence of both wild-type and variant proteins. The observed mass results for the wild-type and variant proteins were consistent with the predicted values calculated from the genetic analysis data.

A new lysozyme tyr54asn mutation causing amyloidosis in a family of Swedish ancestry with gastrointestinal symptoms

Familial amyloidoses are a group of inherited disorders that cause deposition of misfolded amyloidogenic proteins in various tissues, resulting in organ dysfunction. Point mutations in the coding region of seven different genes are known to cause clinically significant systemic amyloid disease. We describe a new mutation in exon 2 of the lysozyme gene associated with amyloidosis (ALys) in a 61-year-old woman with a 7-year history of non-bloody, watery diarrhea, and weight loss. Biopsies of the duodenum and stomach were positive for amyloid deposits in the lamina propria and blood vessels. Direct DNA sequencing of the lysozyme gene revealed a single base nucleotide transversion from T to A at the first position of codon 54, resulting in replacement of Tyr by Asn in the mature lysozyme protein (pTyr54Asn). Immunoblot analysis of amyloid fibrils extracted from a fat tissue sample confirmed lysozyme as the amyloid protein. Clinically, the phenotype associated with this lysozyme mutation featured chronic abdominal pain, diarrhea, weight loss, malabsorption, and sicca syndrome. There was no associated nephropathy as has been reported for other ALys mutations. We describe a new mutant lysozyme that presents with abdominal discomfort, diarrhea, weight loss, and sicca syndrome.

A Proteomic Approach to the Study of Systemic Amyloidoses

Introduction Protein deposition as amyloid is the basis of diseases that, overall, have an enormous social and medical impact. At least 24 different proteins are known to be causative agents (1). In the systemic forms, amyloid deposition is associated with dysfunction of vital organs, and molecular typing of the deposits is necessary for diagnosis and treatment (2). The traditional diagnostic approach is multidisciplinary, but sometimes fails to identify the correct type. A proteomic approach could help in diagnosis, through the direct molecular characterization of fibrillar proteins in tissues, and cast insights into the mechanisms of tissue damage. We developed a method to characterize amyloid deposits in abdominal subcutaneous fat obtained by fine needle aspiration (3) from patients with systemic amyloidosis, using 2D-PAGE followed by MALDI-TOF MS and peptide mass fingerprinting.

Use of Serum Transthyretin as a Prognostic Indicator and Predictor of Outcome in Cardiac Amyloid Disease Associated With Wild-Type Transthyretin

Background: Wild-type transthyretin amyloidosis (ATTRwt), an underappreciated cause of heart failure in older adults, is challenging to diagnose and monitor in the absence of validated, disease-specific biomarkers. We examined the prognostic use and survival association of serum TTR (transthyretin) concentration in ATTRwt. Methods and Results: Patients with biopsy-proven ATTRwt were retrospectively identified. Serum TTR, cardiac biomarkers, and echocardiographic parameters were assessed at baseline and follow-up evaluations. Statistical analyses included Kaplan–Meier method, Cox proportional hazard survival models, and receiver-operating characteristic curve analysis. Median serum TTR concentration at presentation was 23 mg/dL (n=116). Multivariate predictors of shorter overall survival were decreased TTR, left ventricular ejection fraction and elevated cTn-I (cardiac troponin I); an inclusive model demonstrated superior accuracy in 4-year survival prediction by receiver-operating characteristic curve analysis (area under the curve, 0.77). TTR values lower than the normal limit, <18 mg/dL, were associated with shorter survival (2.8 versus 4.1 years; P=0.03). Further, TTR values at 1- and 2-year follow-ups were significantly lower (P<0.001) in untreated patients (n=23) compared with those treated with TTR stabilizer, diflunisal (n=12), after baseline evaluation. During 2-year follow-up, unchanged TTR corresponded to increased cTn-I (P=0.006) in untreated patients; conversely, the diflunisal-treated group showed increased TTR (P=0.001) and stabilized cTn-I and left ventricular ejection fraction at 1 year. Conclusions: In this series of biopsy-proven ATTRwt, lower baseline serum TTR concentration was associated with shorter survival as an independent predictor of outcome. Longitudinal analysis demonstrated that decreasing TTR corresponded to worsening cardiac function. These data suggest that TTR may be a useful prognostic marker and predictor of outcome in ATTRwt.