Concurrent Paraneoplastic Dermatomyositis and Acquired C1 Esterase Inhibitor Deficiency in Primary Laryngeal Small Cell Carcinoma

Small cell carcinoma is associated with a number of paraneoplastic syndromes. We report a case of a 42-year-old female who presented with primary laryngeal small cell carcinoma associated with concurrent paraneoplastic dermatomyositis and paraneoplastic angioedema secondary to acquired C1 esterase inhibitor deficiency. The patient required extensive treatment for her dermatomyositis including high-dose corticosteroid therapy and intravenous immunoglobulin followed by steroid-sparing disease-modifying immunosuppression. Her angioedema also required multiple lines of therapy including bradykinin inhibitors and human recombinant C1 esterase. We believe this is the first reported case of either of these paraneoplastic syndromes arising from an extrapulmonary small cell carcinoma and highlights the difficulty of its initial diagnosis as well as concurrent management.

Physicochemical and Biological Characterization of rhC1INH Expressed in CHO Cells

The disfunction or deficiency of the C1 esterase inhibitor (C1INH) is associated with hereditary or acquired angioedema (HAE/AAE), a rare life-threatening condition characterized by swelling in the skin, respiratory and gastrointestinal tracts. The current treatment options may carry the risks of either viral infection (plasma-derived Berinert®) or immune reaction (human recombinant C1INH from rabbit milk, Ruconest®). This study describes the physicochemical and biological characterization of a novel recombinant human C1 esterase inhibitor (rhC1INH) from Chinese hamster ovary (CHO) cells for the treatment of hereditary angioedema compared to the marketed products Berinert® and Ruconest®. The mass spectrometry results of total deglycosylated rhC1INH revealed a protein with a molecular mass of 52,846 Da. Almost full sequence coverage (98.6%) by nanoLC-MS/MS peptide mapping was achieved. The purity and C1s inhibitory activity of rhC1INH from CHO cells are comparable with Ruconest®, although we found differences in charge isoforms distribution, intact mass values, and N-glycans profile. Comparison of the specific activity (IC50 value) of the rhC1INH with human C1 esterase inhibitor from blood serum showed similar inhibitory properties. These data allow us to conclude that the novel rhC1INH molecule could become a potential therapeutic option for patients with HAE/AAE.

Minimal Role for the Alternative Pathway in Complement Activation By HIT Immune Complexes

Background: Recent studies show that ultra-large immune complexes consisting of IgG and platelet factor 4 and heparin (P+H) potently activate complement and facilitate complement dependent activation of cellular FcgRIIA (PMID 34189574). In whole blood assays using KKO, a monoclonal anti-PF4/heparin antibody, or antibodies from patients with heparin induced thrombocytopenia (HIT), we showed that classical pathway (CP) inhibition reduced immune complex-mediated complement activation (C3c and soluble C5b-9 generation), cell surface deposition of immune complexes and cellular activation. Aims: As previous studies suggest that the alternative pathway (AP) provides significant amplification (>80%) of the CP pathway, (PMID: 15544620) we compared the effects of AP, CP, and CP/AP inhibitors by KKO and HIT immune complexes in whole blood. Methods: Inhibitors of the CP (BBK32, a borrelia protein inhibitor to C1r), AP (anti-factor B antibody (α-fB), or Factor D (fD inhibitor or fD-INH) Alexion Pharmaceuticals, Boston, MA) or combined AP/CP (C1-esterase inhibitor, C1-INH, Berinert, CSL Behring; or soluble complement receptor 1, sCR1, Alexion) were tested in hemolytic assays of CP or AP to confirm pathway specificity. To examine effects of CP or AP inhibition on complement activation by immune complexes consisting of KKO or HIT IgG, whole blood was pre-incubated with CP, AP or CP/AP inhibitors prior to addition of P+H ± KKO/HIT IgG or isotype controls. WB was incubated for 45 minutes at 37ºC followed by addition of 10mM EDTA to quench further complement activation. Complement activation products (C3c and sC5b-9) and neutrophil degranulation (MMP9) markers were measured using commercial immunoassays. Effects of complement inhibitors on cellular deposition of immune complexes was examined by flow, using previously described methods (PMID 34189574) using fluorescently labeled anti-C3c antibody (Quidel, San Diego, CA) and anti-mouse or human IgG (Biolegend, San Diego, CA). Results: Consistent with prior publications (PMID: 26808924), BBK32 showed marked reduction CP, but not AP-dependent hemolytic assays. The converse was true of AP inhibitors: α-fB and fD-INH prevented AP-dependent, but not CP-dependent hemolysis (data not shown). C1-INH and sCR1 showed activity in both CP- and AP-dependent assays. The CP or CP/AP inhibitors showed potent inhibition of C3c and sC5b-9 generation by KKO and HIT immune complexes, while AP inhibitors had no effect (Figure A for KKO C3c generation; and Table 1 for KKO/HIT C3c generation; sC5b-9 data not shown). For a given CP or CP/AP inhibitor, the concentrations leading to 50% inhibition (IC 50) were generally comparable for KKO and HIT immune complexes for C3c (Figure A and Table 1) and sC5b-9 generation (data not shown), with potency as follows: C1-INH>>BBK32>sCR1 (Table 1). On the other hand, the AP inhibitors, α-fB and fD-INH, showed no inhibitory activity in C3c (Figure A and Table 1)/sC5b-9 (data not shown) generation by KKO or HIT ULICs. As our recent studies indicate that complement activation is critical to cell surface deposition of immune complexes and cellular activation via FcgRIIA, we examined effects of complement inhibitors on IC deposition on B-cells and MMP9 release from neutrophils. CP or CP/AP inhibitors, but not AP inhibitors, reduced cell surface binding of immune complexes (Figure B) as well as MMP9 release (Figure C and Table 1). Conclusion: Together, these studies demonstrate that the AP has a minimal role in supporting complement activation by KKO/HIT ULICs. Future studies should examine CP inhibition as a therapeutic strategy for modulating the cellular activating effects of HIT antibodies. To what extent these findings apply to other immune complexes and/or CP activators requires further study. Funding Agency: NIH HL151730; α-fB antibody, fD inhibitor and sCR1 was provided by Alexion Pharmaceuticals, Boston, MA. BBK32 was provided by Dr. Brandon Garcia, East Carolina University, Greenville, NC. Figure 1 Figure 1. Disclosures Cines: Dova: Consultancy; Rigel: Consultancy; Treeline: Consultancy; Arch Oncol: Consultancy; Jannsen: Consultancy; Taventa: Consultancy; Principia: Other: Data Safety Monitoring Board. OffLabel Disclosure: C1-esterase inhibitor off label for HIT

Successful use of lanadelumab in an elderly patient with type II hereditary angioedema

Hereditary angioedema (HAE) is a rare genetic disorder characterized by recurring episodes of subcutaneous and/or submucosal edema without urticaria due to an excess of bradykinin (1, 2). HAE is classified into 2 main types (1). Type I HAE is caused by deficiency of C1 esterase inhibitor, accounting for 85% of cases (1). Type II HAE occurs in only 15% of cases and is marked by normal to elevated levels of C1 esterase inhibitor but with a reduction in activity (1). An angioedema attack can range in severity depending on the location and degree of edema (2). Furthermore, patients with HAE are often diagnosed with anxiety and depression secondary to their poor quality of life (3). Thus, long-term prophylaxis of attacks can be crucial to reduce the physical and psychological implications. For long-term prophylaxis, lanadelumab, a subcutaneously delivered monoclonal antibody inhibitor of plasma kallikrein, has been proven to decrease the frequency of HAE attacks without significant side effects (4). However, data is limited, specifically regarding patients with type II HAE and patients >/= 65 years (4).

Convalescent plasma does not provide adequate replacement of C1-Inhibitor and complements in COVID-19 patients

The rationale of Convalescent Plasma (CP) is to provide passive immunity to acutely ill COVID-19 patients. However, there are other pathologies of COVID disease that may be alleviated by CP. COVID-19 coagulopathy has been hypothesized to be a form of disseminated intravascular coagulopathy, a type of thrombotic microangiopathy. Complement activation has also been implicated in COVID-19 coagulopathy. An alternative hypothesis for additional benefits of CP is replacement of inhibitors of complements. C1-esterase inhibitor (C1-INH) is a major regulator of complement activation. We hypothesized that COVID-19 patients have decreased C1-INH and that CP transfusion would restore intravascular C1-INH and complement levels. We studied serial C1-INH and complement levels in COVID-19 patients before and after CP transfusion (200 mL) and their association with overall mortality. Methods: We identified COVID-19 patients (n=91) that received CP within the first 72 hours after admission. We collected serum and/or plasma samples at day prior and post-day 1, 3, and 10. C1 inhibitor, C3 and C4 were tested in these samples as well as in the respective CP unit given to each patient. Results: C1-INH levels day before transfusion were increased in COVID-19 patients (201.5% +/- 53%) in comparison to CP (93.2% +/- 26.2%). C1-INH transiently increased post CP transfusion and remained relatively high through day 10. No statistical difference was observed in C1-INH between survivors (n=53) and non-survivors (n=39) at any time point before or after transfusion. C3 was higher in COVID-19 patients in comparison to CP (161.5 +/-47.0 vs. 89.6 +/-15.3 mg/dL). However, C3 levels were significantly lower in non-survivors compared to survivors the day before transfusion (131.9 +/- 38.0 vs. 180.9 +/- 45.1 mg/dL, p=2.8E-06). Following transfusion, C3 levels decreased and remained steady afterwards; at all subsequent time points C3 levels were significantly lower in non-survivors compared to survivors (post-day 1: 130.6+/- 33.0 vs. 158.5 +/- 51.5 mg/dL, p=0.006; post-day 3: 116.6+/-46.5 vs. 146.2+/-42.8 mg/dL, p=0.01; post-day 10: 120.8+/-40.9 vs. 150.3+/- 45.9 mg/dL, p=0.03). C4 levels trended lower in non-survivors compared to survivors the day before transfusion (30.8+/- 15.3 vs. 37.9 +/- 16.7 mg/dL, p=0.08). The day following CP, there was a significant decrease in C4 across the entire cohort (35.1+/- 16.4 vs. 27.9+/- 18.3 mg/dL, p=0.01); subsequent levels remained steady. In conclusion, a single CP transfusion does not appear to restore C1-INH, C3 and C4 levels in hospitalized COVID-19 patients. CP transfusion is associated with a transient increase in C1-INH and decreasing C3 and C4 levels. Contrary to our hypothesis, C1-INH levels are increased in COVID-19 patients. The relationship between C1-INH and complements in COVID-19 remains to be fully elucidated. Prospective studies are needed to further delineate these relationships especially in the context of ongoing clinical trials of recombinant C1-INH in COVID-19 patients.