Exome Sequencing To Define A Genetic Signature Of Plasma Cells In Systemic AL Amyloidosis

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 3098-3098 ◽  
Author(s):  
Brian A Walker ◽  
Dorota Rowczienio ◽  
Eileen M Boyle ◽  
Christopher P Wardell ◽  
Sajitha Sachchithanantham ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Exome Sequencing ◽  
Plasma Cell ◽  
Copy Number ◽  
Monoclonal Gammopathy ◽  
Plasma Cells ◽  
Chromosomal Abnormalities ◽  
Light Chains ◽  
Al Amyloidosis ◽  
Plasma Cell Disorders

Abstract Systemic amyloid light chain amyloidosis (AL) is characterized by the deposition of immunoglobulin light chains as amyloid fibrils in different organs, where they form toxic protein aggregates. Most AL patients have relatively low levels of circulating free light chains and bone marrow plasmacytosis. The underlying disease is a plasma cell disorder, likely a monoclonal gammopathy, but limited data are available on the biology of the plasma cell clone underlying AL and existing studies have concentrated on chromosomal abnormalities. Many of the chromosomal abnormalities identified in AL are also seen in other plasma cell disorders, such as monoclonal gammopathy of undetermined significance (MGUS) and myeloma. These abnormalities include translocations involving the IGH locus, gains of 1q and deletions of 13q and 17p. Fluorescence in situhybridization studies have identified the translocation t(11;14) to be more frequent in AL and hyperdiploidy to be rare. The causal link between genetic changes in plasma cells and light chain instability remains unknown and progression to symptomatic myeloma is rare. We report the initial findings of the first exome sequencing to define the plasma cell signature in AL and compared this to MGUS and myeloma. CD138+ cells were selected using either EasySep (Stem Cell Technologies) or MACSort (Miltenyi) from the bone marrow of 18 AL patients and 5 MGUS patients. DNA was extracted from the CD138+ cells using the AllPrep kit (Qiagen). Non-involved DNA was isolated from peripheral white blood cells using the Flexigene kit (Qiagen). 200 ng DNA was subjected to exome sequencing using NEBNext kit (NEB) and SureSelect Human All Exon kit v5 and sequenced using 76-bp paired end reads. Fastq files were aligned to the reference genome using BWA and Stampy aligners. BAM files were recalibrated using the GATK and deduplicated using Picard. Paired tumour/normal BAMs were realigned together using the GATK indel realigner and SNVs were called using Mutect. Copy number data were estimated using the R package ExomeCNV. The median depth across all samples was 42x with 97% of the exome covered at 1x and 72% covered at 20x. Exome data to determine the cytogenetic groups of AL samples identified 42% hyperdiploid and 21% with t(11;14). The AL samples with t(11;14) did not contain any other copy number abnormalities. Exome sequencing on samples from patients with MGUS and myeloma was also performed to compare the genetic makeup and mutation spectrum of these well characterised plasma cell neoplasias with AL samples. MGUS samples had a median of 30 acquired nonsynonymous variants (range 24-189) and AL amyloidosis samples had a median of 17 acquired nonsynonymous variants (range 4-44). The AL samples had four recurrent mutations in PCMTD1 (n=3; L267F, P266S and M187I), C21orf33 (n=2; E72K), NLRP12 (n=2; L1018P, W959* ) and NRAS (n=2; Q61R, Q61H). In this small dataset, only 5 genes were mutated in both the MGUS and AL samples (DNMBP, FRG1, HIST1H1B, KRTAP4-11 and MCCC1). In order to assess the similarity (or differences) of plasma cells in AL to malignant plasma cells in general, we compared them to a random sampling of 20 multiple myeloma samples which had also been exome sequenced (median number of acquired nonsynonymous variants = 39 vs. 17 in AL samples). This revealed that the AL contained 21 mutated genes in common with the myeloma cohort, including DIS3 and NRAS. There were two DIS3 mutations in one AL sample at c.379D>E (p.D479E) and c.1999A>T (p.M667L), both of which were in the Ribonuclease II/R catalytic domain. Data on correlation of gene mutations and organ involvement in AL amyloidosis will be presented. We conclude that exome sequencing identifies a genetic signature of AL amyloidosis which is similar to other plasma cell disorders. This not only includes copy number abnormalities and translocations but also a similar number of nonsynonymous mutations to MGUS and fewer than the advanced myeloma samples. Study of further samples is in progress. Disclosures: No relevant conflicts of interest to declare.

Exome Sequencing to Define a Genetic Signature of Plasma Cells in Systemic AL Amyloidosis

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 726-726 ◽  
Author(s):  
Eileen M Boyle ◽  
Brian A Walker ◽  
Dorota Rowczienio ◽  
Christopher P Wardell ◽  
Alexander Murison ◽  
...  
Keyword(s):  
B Cell ◽  
Exome Sequencing ◽  
Whole Exome Sequencing ◽  
Plasma Cell ◽  
Plasma Cells ◽  
Al Amyloidosis ◽  
Newly Diagnosed ◽  
Mutational Landscape ◽  
Genetic Signature ◽  
Whole Exome

Abstract Introduction: Systemic light chain amyloidosis (AL) is characterized by the deposition of immunoglobulin light chains as amyloid fibrils in different organs, where they form toxic protein aggregates. The underlying disease is a plasma cell disorder, likely a monoclonal gammopathy, but limited data are available on the biology of the plasma cell clone underlying AL and existing studies have concentrated on chromosomal abnormalities. We report the final findings of the first exome sequencing to define the plasma cell signature in AL and compared this to other mature lymphoid malignancies. Methods: Whole exome sequencing was performed on 27 newly diagnosed, histologically proven amyloidosis patients. DNA was extracted from peripheral blood and CD138+ plasma cells and whole exome sequencing was performed using SureSelect (Agilent). In addition to capturing the exome, extra baits were added covering the IGH, IGK, IGL and MYC loci in order to determine the breakpoints associated with translocations in these genes. Tumour and germline DNA were sequenced and data processed to generate copy number, acquired variants and translocation breakpoints in the tumour. Patient demographics: The median age at diagnosis was 69 (range: 41-81) years old. All cases were histologically proven, newly diagnosed AL amyloid. 74% were lambda restricted and 26% kappa with median respective median involved sFLC were 180 mg/L (range: 58.9-986 mg/L) and 730 mg/L (609-3190 mg/L) respectively. The median plasmocytosis was 17.5% (range: 2-90%). 78% of them had evidence of heart involvement, 70% had renal involvement and 33% had liver involvement. Mutation load: The median number of acquired non-synonymous variants per sample was 65 (range 7-285) with 40 (4-251) potentially disease causing variants per sample. Mutational landscape: Although no genes were significantly mutated, the genes closest to significance were NRAS, PIM1, and HIST1H3F. We identified 2 cases with NRAS mutations in the codon 61 (Q61R and Q61H) but no KRAS mutations were seen. Interestingly, there were mutations in some of the significantly mutated genes in myeloma such as EGR1 (Q95R), DIS3 (M505L and D317E) and TRAF3 (splice site). One patient bore a CARD11 (R1077W) mutation, more commonly seen in non-Hodgkin’s lymphoma. Although 22% of our samples had a t(11;14) translocations we did not observe any mutations in CCND1. We identified a t(1;14) (p36;q32) previously described in non-hodgkin lymphoma in one patient. We also identified a Myc translocation in a patient who met the criteria for smouldering myeloma. As previously described in myeloma, both DIS3 mutants occurred in patients with a del(13q). Finally, there was no APOBEC signature in our small samples cohort butwe identified an unspecific mutational signature that was related to age. When comparing the spectrum of mutated genes in both amyloidosis (n=27) and previously sequenced myeloma samples (n=463), we identified 948 genes in common between myeloma and amyloidosis. Four hundred and forty two genes were only mutated in amyloidosis most of them being in housekeeping genes. The clustering of the most frequent and significantly mutated genes in each B-cell malignancy, suggests amyloidosis resembles myeloma and MGUS more than other B-cell malignancies. Discussion: The mutational landscape of amyloidosis resembles myeloma with no disease defining mutations but a variety of mutations occurring in different pathways such as RAS and NF-kB. Two samples had an NRAS mutation, which is a known driver mutation also found in MM. We identified a non-canonical IgH translocation that is a rare event in myeloma. There was little overlap in mutated genes indicating a diverse spectrum of mutations, which is in common with MM. Given the diverse mutational spectrum it will be necessary to study a large cohort to fully understand the genetic complexity of the disease. Conclusion: We conclude that exome sequencing identifies a genetic signature of AL amyloidosis which is similar to other plasma cell disorders in terms of translocations and non-synonymous mutations. Disclosures Walker: Onyx Pharmaceuticals: Consultancy, Honoraria.

scholarly journals Significance of Bone Marrow Plasma Cell Percentage in Patients with Monoclonal Gammopathy of Unknown Significance Developing Multiple Myeloma

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 5688-5688
Author(s):  
Mona L Vekaria ◽  
Bharat Rao ◽  
Philip Kuriakose
Keyword(s):  
Risk Factors ◽  
Bone Marrow ◽  
Bone Marrow Biopsy ◽  
Plasma Cell ◽  
Monoclonal Gammopathy ◽  
Plasma Cells ◽  
Time To Progression ◽  
Bone Marrow Biopsies ◽  
Monoclonal Protein ◽  
Cell Percentage

Abstract Introduction: Monoclonal gammopathies are characterized by the detection of a monoclonal immunoglobulin in the serum or urine and underlying proliferation of a plasma cell/B lymphoid clone. (1) Patients with monoclonal gammopathy of undetermined significance (MGUS) have a clonal plasma cell population in the marrow (<10%) and secrete a monoclonal protein in the serum (<3g/dL) and/or urine. However, they lack clinical features of overt Multiple Myeloma (MM) (lytic bone lesions, anemia, renal impairment and hypercalcemia). In a study from the Mayo Clinic, 59 of 241 patients with MGUS (24%) developed MM over a period of 22 years. (2) The interval from recognition of monoclonal protein to diagnosis of MM ranged from 2-29 years, indicating that patients with MGUS need to be followed indefinitely. Many risk factors have been looked at to identify those with MGUS who are at the highest risk to progress into MM. We hypothesize that a higher number of plasma cells would correlate with a greater risk of progression to MM and sought to find out if this could be documented by arbitrarily dividing patients between < or ≥5% plasma cells seen on initial bone marrow biopsy. Methods: We retrospectively reviewed patients diagnosed with MGUS at Henry Ford Hospital between 1999-2013 who underwent a bone marrow biopsy for documenting plasma cell percentage. In addition to this, we also recorded serum hemoglobin, calcium, creatinine, monoclonal protein type and amount, serum free light chains, beta-2 microglobulin and urine for monoclonal protein at the time of diagnosis of MGUS as well as last completed values. For patients that had skeletal surveys we noted if lytic lesions were present at diagnosis, as well as cytogenetics and karyotype evaluations on bone marrow biopsy samples, if completed. Results: 120 patients with bone marrow biopsies were reviewed. Out of this 17 patients were noted from initial bone marrow biopsy to have ≥10% plasma cells. The remaining 103 patients were categorized as having MGUS. While we were not able to complete full statistical analyses, we did note that 14 of these 103 (13.6%) patients went on to develop overt MM. Further evaluation of these patients revealed that 8 of 14 (57%) had bone marrow biopsies showing ≥5% plasma cells. Interestingly the average time to progression into MM in this subgroup was 1,879 days whereas in the 6 of 14 (43%) with bone marrow biopsy showing <5% plasma cells had average time to progression into MM of 1,965 days. Abnormal cytogenetics and karyotypes of the bone marrow biopsy were also seen in 37.5% of the subgroup of patients with ≥5% plasma cells whereas it was only seen in 16.7% of the subgroup of patients with <5% plasma cells. With statistical data analyses we hope to prove significance in the above collected data as well as make further correlations in regards to risk factors in patients with MGUS. Conclusion: While we have not been able to complete full statistical analyses of the collected data yet, basic review of the above patients with MGUS and ≥5% plasma cells in the bone marrow biopsy showed a trend to develop MM faster by an average of 86 days than those that had <5% plasma cells. These same patients also were more likely to have abnormal cytogenetics and karyotypes of their bone marrow biopsies. There is a need for further investigations to be done in patients with MGUS and higher risk features. It is important that hematologists be able to recognize a high risk MGUS patient as this would lead to closer monitoring and consideration for earlier aggressive treatment to potentially delay progression into overt MM. Disclosures No relevant conflicts of interest to declare.

scholarly journals Follow-up Care of Monoclonal Gammopathy of Undetermined Significance: A Guide for Primary Care Physicians

2021 ◽  
Vol 8 (5) ◽  
Author(s):  
Hammad Z ◽  
◽  
Hernandez E ◽  
Tate S ◽  
◽  
...  
Keyword(s):  
Plasma Cell ◽  
Primary Care Physicians ◽  
Monoclonal Gammopathy ◽  
Plasma Cells ◽  
Organ Damage ◽  
M Protein ◽  
Bone Lesions ◽  
Al Amyloidosis ◽  
End Organ Damage ◽  
Undetermined Significance

Monoclonal Gammopathy of Undetermined Significance (MGUS) is a condition in which M protein, an abnormal monoclonal immunoglobulin, is present in the blood at a nonmalignant level. Specifically, it is defined by: blood serum M protein concentration <3 g/dL (<30 g/L), <10% plasma cells in the bone marrow, and no evidence of end organ damage [1,2]. Evidence of end organ damage includes hypercalcemia, renal insufficiency, anemia, and bone lesions. These are indicative of MGUS progression and which can be attributed to the monoclonal plasma cell proliferative process [3]. MGUS occurs in 3% of the general population older than 50 years. Incidence increases with age and varies with sex with higher rates observered in males than females [1,4]. MGUS is the most common plasma cell disorder, with 60% of patients that present to the Mayo Clinic with a monoclonal gammopathy being diagnosed with MGUS [3]. While it is typically an asymptomatic condition, it is premalignant disorder to other monoclonal gammopathies. Multiple Myeloma (MM) is almost always preceded by MGUS and the majority of patients will have detectable levels of M protein for at least 5 years prior to MM diagnosis [5,6]. MGUS also precedes immunoglobulin light chain (AL) amyloidosis and Waldenstrom Macroglobulinemia (WM) and tends to progress to disorders at a fixed but unrelenting rate of 1% per year [4].

Expression of CD126 (IL-R alpha) on Plasma Cells in Monoclonal Gammopathies.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 5066-5066
Author(s):  
Syed T. Mahmood ◽  
Shaji Kumar ◽  
Teresa K. Kimlinger ◽  
Jessica L. Haug ◽  
Michael Timm ◽  
...  
Keyword(s):  
Plasma Cell ◽  
Monoclonal Gammopathy ◽  
Plasma Cells ◽  
Cell Subset ◽  
Primary Amyloidosis ◽  
Normal Plasma ◽  
Plasma Cell Disorders ◽  
Plasma Cell Disorder ◽  
Cell Disorder

Abstract Background: IL-6 is important for proliferation and inhibition of apoptosis in malignant plasma cells. Understanding the role of IL-6 receptor alpha chain (CD126) in the pathogenesis of plasma cell disorders may help in developing future treatment therapies for these diseases. A previous study has shown that CD126 (alpha subunit of IL-6 receptor) is expressed distinctly in myeloma, monoclonal gammopathy of unknown significance (MGUS), and plasmacytomas when compared to normal. We performed this study in order to confirm and describe the expression of CD126 in different plasma cell disorders. Design and Methods: Using flow cytometry we assessed CD126 expression on clonal plasma cells from patients with Primary Amyloidosis (n=7), monoclonal gammopathy of undetermined significance (MGUS) (n=13), smoldering Myeloma (SMM) (n=19) and active Myeloma (n=22), as well as normal plasma cells (n=9). Plasma cells were identified by their characteristic CD38/45 expression. The expression of CD126 was separately analyzed on the CD45 positive and negative plasma cells. CD 126 expression was considered significant when more than 20% of the cells had expression. Results: CD126 expression was seen distinctly in plasma cell disorder plasma cells and not in normal plasma cells when all plasma cells were studied together. The highest expression percentages were found in Amyloid (28%) followed closely by MGUS 29(%), then SMM (23%), and Myeloma (12%) cells. The CD45 neg subset was similarly positive in the plasma cell disorder group. In this group, MGUS showed the highest expression percentage followed distantly by Amyloid, Myeloma, and SMM. The CD45 pos subset was uniformly positive in expression of CD126. If was found that this subset expressed higher levels of CD126 in all the studied plasma cell disorders and normal plasma cells when compared to the CD45 neg subset. Conclusion: The findings of this study confirm the increased expression of CD126 in plasma cell disorders when compared to normal plasma cells. The higher expression of CD126 in the CD45 pos plasma cell subset has not been previously described. In addition, the CD45 pos subset expressed higher levels of CD126 in all study groups when compared to the CD45 pos subset. This data contributes to the understanding of IL-6 receptor physiology and confirms the important role of the CD45 pos subset in the proliferation of neoplastic plasma cells. The findings are in accordance with the increased proliferative rates seen in the CD45 fraction of malignant plasma cells.

AL Amyloidosis and Concomitant Myeloma: Time to Reconsider Assumptions

Blood ◽  
2010 ◽  
Vol 116 (21) ◽  
pp. 4044-4044
Author(s):  
Wesley Witteles ◽  
Ronald Witteles ◽  
Michaela Liedtke ◽  
Sally Arai ◽  
Richard Lafayette ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Overall Survival ◽  
Plasma Cell ◽  
Research Funding ◽  
Plasma Cells ◽  
Renal Involvement ◽  
World Health ◽  
Bone Lesions ◽  
Al Amyloidosis ◽  
Bone Marrow Biopsies

Abstract Abstract 4044 Background: Conventionally, multiple myeloma is believed to coexist in approximately 10% of AL amyloidosis patients. However, it is unclear whether this figure is too low based on current World Health Organization criteria. These criteria, mainly created to differentiate myeloma from monoclonal gammopathy of undetermined significance, include the presence of ≥ 10% plasma cells on a bone marrow biopsy or aspirate as being diagnostic of myeloma. Aims: To define the frequency and relevance of a concomitant diagnosis of myeloma in patients with AL amyloidosis. Methods: Records from consecutive patients with biopsy-proven AL amyloidosis treated at the Stanford University Amyloid Center were reviewed. Plasma cell percentages were determined by manual counts from bone marrow aspirate smears and by CD138 immunohistochemistry (IHC) performed on bone marrow core biopsies. Results: A total of 41 patients (median age 61 years, 32% female) were evaluated. The median number of organs involved with amyloidosis was 2 (range 1–4), with 28 patients (68%) having cardiac involvement, 22 patients (54%) having renal involvement, 15 patients (37%) having gastrointestinal involvement, 12 patients (29%) having soft tissue involvement, and 10 patients (24%) having nervous system involvement. All patients had bone marrow biopsies and aspirates performed at the time of amyloid diagnosis, with most undergoing both manual counts of plasma cells from aspirates and IHC from core biopsies. Based on conventional criteria, manual aspirate counts defined 15/28 (54%) patients as having myeloma, and IHC defined 26/31 (84%) patients as having myeloma (p=0.01). Only nine patients had a detectable serum paraprotein on immunofixation (median 1.1 g/dl, range 0.4–2.6). 81% of patients had an elevated serum free light chain (85% lambda), with a median level of 37.3 mg/dl (range 8.6–256 mg/dl). Compared to the frequency of elevated plasma cells, the prevalence of anemia (29%), hypercalcemia (14%), impaired kidney function (21%), and lytic lesions (7%) was low. After a median follow-up of 13 months (range 1–127 months), the one-year overall survival (74% vs. 58%) and three-year overall survival (50% vs. 50%) was not significantly different between patients with ≥10% plasma cells and patients with <10% plasma cells (p=NS). Discussion: As defined by bone marrow plasma cell involvement, a strikingly high percentage (84%) of AL amyloidosis patients would be considered to have concurrent myeloma. This figure is much higher than has been traditionally quoted in the literature, likely due to the utilization of newer methods of counting plasma cells. There was a low prevalence of myeloma-associated end-organ effects (hypercalcemia, anemia, renal insufficiency, lytic bone lesions), and a myeloma diagnosis had no impact on survival. Conclusion: In this cohort of AL amyloid patients, concomitant myeloma was present in the vast majority of patients using modern diagnostic techniques. The significance of this diagnosis appears to be minimal – calling into question whether the diagnostic criteria for myeloma should be redefined in this population. Disclosures: Witteles: Celgene: Research Funding. Liedtke:Celgene: Lecture fee, Research Funding. Schrier:Celgene: Research Funding.

Bone Marrow Biopsy May Be Required During the Initial Evaluation of Individuals with Asymptomatic Monoclonal Gammopathy

Blood ◽  
2011 ◽  
Vol 118 (21) ◽  
pp. 5067-5067
Author(s):  
Meletios Athanasios Dimopoulos ◽  
Evangelos Terpos ◽  
Maria Gkotzamanidou ◽  
Evangelos Eleutherakis-Papaiakovou ◽  
Magdalini Migkou ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Bone Marrow Biopsy ◽  
Plasma Cell ◽  
Light Chain ◽  
Monoclonal Gammopathy ◽  
Plasma Cells ◽  
Conflicts Of Interest ◽  
Incidental Finding ◽  
M Protein ◽  
Monoclonal Protein

Abstract Abstract 5067 The incidental finding of a monoclonal gammopathy during workup for various conditions or in the context of a routine check-up is increasingly common. Several “patients” are then referred for diagnostic evaluation of their monoclonal gammopathy and additional workup is needed. It has been proposed that a bone marrow (BM) aspirate and biopsy is indicated when the monoclonal protein (M-protein) is ≥1.5 g/dL, when abnormalities are noted in the complete blood cell count, serum creatinine level, serum calcium level, or radiographic bone survey, in individuals with non-IgG monoclonal gammopathy and in those with an abnormal serum free light chain (FLC) ratio. The aim of this study was to identify factors that could aid in the evaluation of individuals presenting with asymptomatic monoclonal gammopathy and in whom invasive diagnostic testing with a bone marrow biopsy is considered. Thus, we analyzed our database and identified patients who were referred to the Department of Clinical Therapeutics of the University of Athens, Greece, for evaluation of asymptomatic monoclonal gammopathy and in whom a BM trephine biopsy, a serum and urine protein electrophoresis (SPEP) with immunofixation and quantitative immunoglobulins were performed. SPEPs were scanned and M-protein was measured using imaging analysis software. Patients with a monoclonal M-protein ≥ 3 g/dl (30 g/L), i.e. those diagnosed with asymptomatic/smoldering myeloma (SMM) or Waldenstrom's macorglobulinemia based on the standard criteria, were not included in the analysis. Clonality of BM plasma cells or lymphoplasmacytes was assessed by immunohistochemistry. Patients who eventually were diagnosed with plasma cell related conditions (i.e. amyloidosis, peripheral neuropathy, dermatoses, etc.) were also excluded from the analysis. Our analysis included 161 patients: 53% were females, median age was 64 year (range 33–89 years), 53% had a monoclonal IgG protein, 15.5% had a monoclonal IgA protein, 24% a monoclonal IgM protein and 2.5% had only a monoclonal light chain, while 4% had a biclonal protein. In 64% of patients the monoclonal light chain was kappa and in 37% was lambda. The median serum M-protein was 0.948 g/dl (range 0.1–2.99 g/dl); 52% of patients had an M-protein of <1 g/dl and 79% of <2 g/dl. Immunoparesis of at least one of the uninvolved immunoglobulins was present in 38% of cases and of both of the uninvolved immunoglobulins in 6%. Median BM infiltration by monoclonal plasma cells or lymphoplasmacytes was 15%. In 66.5% of individuals there was a BM infiltration of ≥10% by monoclonal plasma cells or lymphoplasmacytes, while in 10% of the studied cases the BM infiltration was ≥50%. A significant correlation of the size of M-protein and of the infiltration of the BM was found (R=0.592, p<0.001). However, 27% of patients with M-protein <0.5 g/dl had ≥10% clonal plasma cells or lymphoplasmacytes in their BM biopsies. The respective rates were 46% for those with M-protein <1 g/dl, 54% for those with M-protein 1.5 g/dl and 58% for those with M-protein <2 g/dl. Ninety per cent of those who had immunoparesis of at least one of the uninvolved immunoglobulins had ≥10% clonal plasma cells or lymphoplasmacytes. A BM infiltration of ≥10% was more frequent in individuals with a monoclonal IgG or IgA protein (72% and 80%, respectively) vs. 45% of those with a monoclonal IgM protein (p=0.015). Light chain isotype, age and gender were not predictive of the degree of BM plasma cell infiltration. In multivariate analysis, immunoparesis of at least one of the uninvolved immunoglobulins (OR: 6.45, 95% CI: 2.32–18, p<0.001), an IgG or IgA monoclonal protein (OR: 2.67, 95% CI: 1.1–6.4, p=0.028) and an M-protein of ≥1 g/dl (OR: 5.4, 95% CI: 2.23–13) were independently associated with the presence of ≥10% of clonal infiltration in BM biopsy. By combining the above risk factors we found that in those who had all three, 97% had ≥10% clonal cells in the BM biopsy, while in those with 0–1 of the above factors the probability to find ≥10% clonal cells was 43%. These findings indicate that even patients with low risk for BM infiltration by clonal plasma cells, may be diagnosed as SMM when a BM biopsy is performed. In conclusion, our data on a large number of individuals with asymptomatic monoclonal gammopathy who underwent a BM biopsy may indicate that the latter exam may provide useful information and could be included in the standard initial workup of these individuals. Disclosures: No relevant conflicts of interest to declare.

scholarly journals The Use of Next Generation Gene Sequencing to Measure Minimal Residual Disease in Patients with AL Amyloidosis and Low Plasma Cell Burden: A Feasibility Study

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 4353-4353 ◽  
Author(s):  
Shayna Sarosiek ◽  
Vaishali Sanchorawala ◽  
Mariateresa Fulcinti ◽  
Allison P. Jacob ◽  
Nikhil C. Munshi ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Minimal Residual Disease ◽  
Plasma Cell ◽  
Peripheral Blood ◽  
Research Funding ◽  
Plasma Cells ◽  
Residual Disease ◽  
Al Amyloidosis ◽  
Next Generation ◽  
Minimal Residual

Background: AL amyloidosis is a bone marrow disorder in which clonal plasma cells produce light chains that misfold and deposit in vital organs, such as the kidneys and heart, leading to organ failure and eventual death. Treatment is directed towards the clonal plasma cell population in an effort to halt the production of toxic light chains and recuperate organ function. Pallidini et al. demonstrated that almost 50% of patients with AL amyloidosis who achieved a complete hematologic response to prior therapy had minimal residual disease (MRD) detectable in their bone marrow by multiparametric flow cytometry (MPF).1. Next generation gene sequencing (NGS) has been a successful tool in measuring MRD among patients with multiple myeloma2 though the data regarding its use in AL amyloidosis are limited. AL amyloidosis is a disease with a much smaller plasma cell burden at baseline (typically 5-10%), making the task of isolating an initial clonal sequence even more challenging. We sought to evaluate NGS as a method of isolating a clonal population of plasma cells among patients with systemic AL amyloidosis in a first-ever feasibility study. Methods: Patients were eligible if they had systemic AL amyloidosis and no clinical evidence of concurrent active multiple myeloma. In this study, feasibility was deemed successful if discovery of a clone could be achieved in 3 out of 10 of patients. Approximately five cc's of peripheral blood and bone marrow aspirate were collected from each patient and processed for CD138 selection and DNA isolation/purification. De-identified samples were sent to Adaptive Biotech Inc. (Seattle, WA) for initial clonal identification using the ClonoSEQ immunoglobulin heavy chain (IGH) assay. Genomic DNA was amplified by implementing consensus primers targeting the IGH complete (IGH-VDJH) locus, IGH incomplete (IGH-DJH) locus, immunoglobulin κ locus (IGK) and immunoglobulin l locus (IGL). The amplified product was sequenced and a clone identified based on frequency. After proof of feasibility in the first 10 patients an additional 27 patients had initial clonal identification via the same process mentioned above. Results: In total, 37 patient samples underwent NGS via the ClonoSEQ IGH assay method. The median patient age was 66 years old (range: 44 to 83), 24% of which were female. All 37 patients had measurable disease based on serum electrophoresis and immunofixation and/or serum free light chain assay (Table 1). Four patients had no monoclonal protein detected on SIFE or UIFE and 13 patients had a normal sFLC ratio. Of the 33 patients with monoclonal disease on immunofixation, 12 patients had only a free lambda monoclonal protein and the remaining 21 patients had a clonal heavy chain with an associated light chain. Bone marrow biopsies demonstrated clonal plasmacytosis of 40% or lower. ClonoSEQ IGH assay identified trackable clones in 31 of 37 patients (84%) (see Table 1). Four patients had at least one trackable sequence (range: 1 to 5 sequences) in the peripheral blood and 29 patients had at least one trackable sequence in the bone marrow aspirate (range: 1 to 7 sequences). No correlation was seen between the detection of a clone and standard measures of plasma cell tumor burden (SIFE, SPEP, UIFE, UPEP, and sFLCs). Conclusion: NGS was successful in identifying an initial clone in 29 of 37 patients with systemic AL amyloidosis, four of which were detectable in the peripheral blood. Due to the low clonal burden in patients with AL amyloidosis, it is often difficult to assess disease status, especially post-treatment. These encouraging results may enhance disease monitoring and improve patient care in this rare disease. We are currently tracking MRD in the patients with identifiable clones as they receive systemic treatment, the results of which will be available for presentation in December 2019. REFERENCES 1. Palladini G, Massa M, Basset M, Russo F, Milani P, Foli A, et al. Persistence of Minimal Residual Disease By Multiparameter Flow Cytometry Can Hinder Recovery of Organ Damage in Patients with AL Amyloidosis Otherwise in Complete Response. Abstr 3261. 2016; 2. Ladetto M, Brüggemann M, Monitillo L, Ferrero S, Pepin F, Drandi D, et al. Next-generation sequencing and real-time quantitative PCR for minimal residual disease detection in B-cell disorders. Leukemia. 2014;28:1299-307. Table 1 Disclosures Sarosiek: Acrotech: Research Funding. Sanchorawala:Proclara: Consultancy, Honoraria; Takeda: Research Funding; Caelum: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees; Janssen: Research Funding; Prothena: Research Funding; Celgene: Research Funding. Jacob:Adaptive Biotechnologies: Employment, Other: shareholder. Munshi:Amgen: Consultancy; Adaptive: Consultancy; Celgene: Consultancy; Celgene: Consultancy; Janssen: Consultancy; Janssen: Consultancy; Takeda: Consultancy; Takeda: Consultancy; Oncopep: Consultancy; Oncopep: Consultancy; Amgen: Consultancy; Abbvie: Consultancy; Abbvie: Consultancy; Adaptive: Consultancy.

scholarly journals AL Amyloidosis — Pathogenesis and Prognosis Are Determined By the Amyloidogenic Potential of the Light Chain and the Molecular Characteristics of Malignant Plasma Cells

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 187-187
Author(s):  
Anja Seckinger ◽  
Ute Hegenbart ◽  
Susanne Beck ◽  
Martina Emde ◽  
Tilmann Bochtler ◽  
...  
Keyword(s):  
Gene Expression ◽  
Plasma Cell ◽  
Light Chain ◽  
Research Funding ◽  
Plasma Cells ◽  
Memory B Cells ◽  
Light Chains ◽  
Molecular Characteristics ◽  
Al Amyloidosis ◽  
Malignant Plasma Cell

Abstract INTRODUCTION. Systemic light chain amyloidosis (AL) is caused by accumulation of plasma cells producing misfolded monoclonal light chains depositing as amyloid fibrils in different organs, most frequently heart and kidney. AIM of our study is first assessing the molecular characteristics of malignant plasma cells from AL-patients in relation to those from MGUS, asymptomatic, and symptomatic myeloma: Are these plasma cells different, does this difference explain amyloidogenicity? Does AL correspond to a certain developmental stage during evolution of symptomatic myeloma? Secondly, to what extent is prognosis determined by amyloid-deposition (organotropism, amount, amyloidogenicity) vs. number and molecular characteristics of malignant plasma cells? PATIENTS & METHODS . Consecutive patients (n=3023) with AL (n=582), MGUS (n=306), asymptomatic (n=444, AMM), or previously untreated, therapy-requiring multiple myeloma (n=1691, MM) were included. CD138-purified plasma cell samples were subjected to iFISH (n=582/306/444/1691), 1297 to gene expression profiling using Affymetrix U133 2.0 plus arrays (n=196/64/272/765), 712 to RNA- (n=124/52/38/489), and 258 to whole exome sequencing (n=115/53/39/51). Samples of normal bone marrow plasma cells, memory B-cells, and polyclonal plasmablasts were used as comparators. The CoMMpass-cohort (n=647) was used as comparator for the mutational spectrum of myeloma. RESULTS . Prognosis. By AL-factors. Expectedly, organ involvement, i.e. heart only vs. kidney only vs. heart+kidney vs. other (overall survival (OS), P=.001), the amount of free light chains (dFLC ≥18 mg/dL, HR=2.56, P=.01), and the cardiac European Mayo IIIB score (I/II/IIIA/IIIB, median OS 110/55/16/3 months, HR=1/1.94/3.73/7.90, P<.001) strongly determine prognosis (Fig. 1A). By malignant plasma cell factors. High proliferation rate (HR=3.58, P=.001) and expression-based risk factors for MM (GEP70 high, HR=2.38, P=.005; Rs-score high HR=4.63, P<.001) identify patients with very adverse prognosis (Fig. 1A). Tumor load, e.g. plasma cell infiltration >10%/>30% (HR=1.31/1.81, P=.01, P=.002) and M-protein ≥ 30g/l (HR=3.01, P=.005), are likewise prognostic (Fig. 1A). In multivariate analysis, all tested AL-specific (European Mayo IIIB score) and malignant plasma cell factors (proliferation or GEP70 and plasma cell infiltration) are independent. Molecular characteristics.iFISH. As MM (96.2%) and AMM (92.8%) AL-patients (93.1%) carry at least one recurrent myeloma typical aberration. The mean number of progression-associated aberrations in AL (n=0.98) fits between MGUS (n=0.85) and AMM (n=1.45) with significant difference compared to AMM (P<.001) unlike to MGUS. Main differences in frequency are found for t(11;14) and hyperdiploidy with a comparable pattern of non-etiologic aberrations. Gene expression (GEP and RNA-seq). Aberrant plasma cells in AL amyloidosis show the least difference with AMM, followed by MGUS and MM. In principal component analysis, AL overlaps with AMM and MGUS, independent of presence or absence of heart involvement (Fig. 1B). Pairwise assessment of similarity using a multivariate generalization of the squared Pearson correlation coefficient shows closest similarity to AMM and MM followed by MGUS, with comparable differences to normal plasma cells, polyclonal plasmablasts, and memory B-cells. Significantly more AL-patients present with higher proliferation rate vs MGUS (P<.001) and AMM (P<.02). AL and MM differ significantly regarding distinct molecular entities as determined by GEP (e.g. TC-classification; Fig. 1C). Mutation spectrum in AL amyloidosis vs. MM. From the 20 most frequently synonymously mutated non-Ig transcripts (CoMMpass-cohort), 16 could likewise be detected in AL amyloidosis, i.e. KRAS, NRAS, IGLL5, DIS3, FAM46C, MUC16, BRAF, TRAF3, PCLO, RYR2, FATA4, CSMD3, TP53, DNAH5, RYR2A, and FLG. CCND1 mutations were significantly more frequent in AL and AMM compared to MM (P=.02). DISCUSSION & CONCLUSION. Pathogenesis and prognosis of AL amyloidosis are explained both by AL-specific and malignant plasma cell characteristics. Aberrant plasma cells in AL amyloidosis show the same aberration- and expression pattern and a "molecular age" between MGUS and AMM, most closely resembling the latter. AL amyloidosis is thus mostly a rather early plasma cell dyscrasia with an unstable and toxic immunoglobulin light chain. Disclosures Seckinger: Celgene: Research Funding; EngMab: Research Funding; Sanofi: Research Funding. Hose:Celgene: Honoraria, Research Funding; Sanofi: Research Funding; EngMab: Research Funding.

Evaluation of the Cytogenetic Aberration Pattern in AL Amyloidosis Compared to Monoclonal Gammopathies Not Requiring Treatment: Translocation t(11;14) Is More Frequent in AL Amyloidosis.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 2500-2500 ◽  
Author(s):  
Tilmann Bochtler ◽  
Stefan O. Schonland ◽  
Anna Jauch ◽  
Christiane Heiss ◽  
Axel Benner ◽  
...  
Keyword(s):  
Plasma Cell ◽  
Monoclonal Gammopathy ◽  
Control Group ◽  
Al Amyloidosis ◽  
Fish Analysis ◽  
Cell Content ◽  
Cytogenetic Aberration ◽  
Cytogenetic Aberrations ◽  
Plasma Cell Disorders ◽  
Unknown Significance

Abstract Introduction: Cytogenetic aberrations (CA) have emerged as important pathogenetic and prognostic factors in plasma cell disorders. However, in AL amyloidosis (AL) only a few reports with small numbers of patients have been published. Methods: Using interphase FISH analysis in CD138+ cells, we evaluated the role of CA in a series of 85 AL patients as compared to 146 patients with a monoclonal gammopathy without treatment requirement in a prospective manner. Our panel included IgH translocations t(11;14), t(4;14), t(14;16) and translocation of 14q32 with an unidentified partner, gains of 1q21, 11q23 and 19q13 as well as deletions of 8p21, 13q14 and 17p13. Using these probes we could detect at least one of these aberrations in 95% of AL and in 88% of the control group. Age, gender and plasma cell content were statistically equally distributed among both groups. Results: The most frequent aberration in AL was t(11;14), which was detected in 45% of AL patients as compared to 26% of the control group (p=0,056). It was strongly associated with the lack of an intact immunoglobulin (p&lt;0,001), thus accounting for the frequent light chain only subtype in AL. Markedly, t(11;14) was more frequently found in combination with gain 11q23 in AL than in the control group (20% versus 6%, p = 0.005). Other frequent aberrations in AL included deletion 13q14 (32%) and gain 1q21 (21%), which were observed in the control group at comparable frequencies (34% and 20%). The overlapping character of the underlying plasma cell disorder in both disease entities was also emphasized by the similarities of branching patterns of the five major CA in cluster analysis applied in 169 patients (figure 1). The relation of clinical parameters and chromosomal aberrations was also evaluated. The analyzed CA had no impact on the organ involvement pattern in AL patients. Conclusions: We observed a high frequency for t(11;14) in AL. Apart from this finding, the cytogenetic patterns known in monoclonal gammopathy of unknown significance and multiple myeloma were widely shared by AL amyloidosis. Figure Figure

Clinical Characteristics and Outcome of Primary AL Amyloidosis in Greece.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 4729-4729
Author(s):  
Michalis Michail ◽  
Efstathios Kastritis ◽  
Sossana Delimpassi ◽  
Marie Christine Kyrtsonis ◽  
Evridiki Michali ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Autonomic Neuropathy ◽  
Congo Red ◽  
Plasma Cells ◽  
Primary Treatment ◽  
Response To Treatment ◽  
Light Chains ◽  
High Dose ◽  
Al Amyloidosis ◽  
Heart Involvement

Abstract Introduction: Primary systemic amyloidosis (AL) is a clonal plasma cells disorder characterized by deposition of amyloid fibrils derived from abnormal light chains, leading to multiorgan involvement and failure. There is no information regarding the clinical, laboratory, treatment characteristics and outcome of such patients in Greece. We performed a retrospective analysis in order to clarify these issues. Patients and Methods: Diagnosis of primary AL amyloidosis was based on positive Congo red staining, immunohistochemistry and the presence of typical clinical and laboratory features. Definition of organ involvement and treatment response was based on established criteria (Gertz et al Am J Hematol 2005). Results: between 1995 and 2007, we identified 109 patients with previously untreated systemic AL amyloidosis. Median age was 66.3 years; 51% were males and lambda-light chain was involved in 74% of patients. Bone marrow biopsy stained positive for Congo-red in 56.5%, immunohistochemical staining was performed in 80 cases: 63 (78.75%) stained positive for λ and 17 for κ light chains. A monoclonal protein by immunofixation was found in the serum and/or urine of 97 (87%) patients. More than 10% bone marrow plasma cells were found in 65%. B2microglobulin was elevated in 36% of patients (median value 2.8 mg/l). The most frequent symptoms at presentation were fatigue and weakness (81%). Heart was involved in 66 (59%), kidney in 79 (71%), liver in 21(19%), GI tract in 17 (16%) and soft tissue in 35 (32%) patients respectively. Symptoms of peripheral and/or autonomic neuropathy were present in 38 (35%) patients. More than two organs were involved in 50 patients (45%). Primary treatment with high-dose dexamethasone based regimens (VAD or pulse Dexamethasone) was used in 45% while 37% of patients were treated with melphalan and prednisone. Six patients (5%) were treated upfront with high dose melphalan and ASCT while another 6 patients were transplanted at a later stage of their disease. Hematologic response was achieved in 50 (46%) including 16 (14.5%) patients who achieved a CR. Organ responses were seen in 32 (29%) patients: 4 had cardiac, 21 renal and 7 liver response respectively while 11 patients had subjective improvement of peripheral or autonomic neuropathy. Median survival from initiation of treatment was 61 months and the 5 year-survival was 44%. Patients with heart involvement or with more than 2 affected organs had a worse prognosis. Survival was significantly longer for patients who responded to primary treatment than for those who did not (p=0.018). Conclusions: Greek patients with AL amyloidosis share the same characteristics with that of patients from other reported studies. Hematologic responses were noted in one-half and organ responses in one-third of patients. Prognosis depended primarily on the presence of heart involvement and on the lack of response to treatment.

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