The complement system and human autoimmune diseases.

Genetic deficiencies of early components of the classical complement activation pathway (especially C1q, r, s, and C4) are the strongest monogenic causal factors for the prototypic autoimmune disease systemic lupus erythematosus (SLE), but their prevalence is extremely rare. In contrast, isotype genetic deficiency of C4A and acquired deficiency of C1q by autoantibodies are frequent among patients with SLE. Here we review the genetic basis of complement deficiencies in autoimmune disease, discuss the complex genetic diversity seen in complement C4 and its association with autoimmune disease, provide guidance as to when clinicians should suspect and test for complement deficiencies, and outline the current understanding of the mechanisms relating complement deficiencies to autoimmunity. We focus primarily on SLE, as the role of complement in SLE is well-established, but will also discuss other informative diseases such as inflammatory arthritis and myositis.

Complement C6 deficiency exacerbates pathophysiology after spinal cord injury.

Historically, the membrane attack complex, composed of complement components C5b-9, has been connected to lytic cell death and implicated in secondary injury after a CNS insult. However, studies to date have utilized either non-littermate control rat models, or mouse models that lack significant C5b-9 activity. To investigate what role C5b-9 plays in spinal cord injury and recovery, we generated littermate PVG C6 wildtype and deficient rats and tested functional and histological recovery after moderate contusion injury using the Infinite Horizon Impactor. We compare the effect of C6 deficiency on recovery of locomotor function and histological injury parameters in PVG rats under two conditions: (1) animals maintained as separate C6 WT and C6-D homozygous colonies; and (2) establishment of a heterozygous colony to generate C6 WT and C6-D littermate controls. The results suggest that maintenance of separate homozygous colonies is inadequate for testing the effect of C6 deficiency on locomotor and histological recovery after SCI, and highlight the importance of using littermate controls in studies involving genetic manipulation of the complement cascade.

Clinical implications of C6 complement component deficiency.

Background: Terminal complement component deficiencies are risk factors for neisserial infections. Objective: To review the clinical characteristics, the diagnosis and the management of patients with a terminal complement component deficiency. Methods: Pertinent articles were selected and reviewed in relation to a case presentation of C6 deficiency. Results: A case of a 56-year old patient with a history of meningitis, chronic rash, and C6 deficiency was presented, followed by discussion of clinical characteristics, diagnosis, and management of terminal complement component deficiencies. Clinical pearls and pitfalls were reviewed for the practicing allergist/immunologist and fellow-in-training. Conclusion: C6 deficiency is the most common terminal complement component deficiency and can present later in age with N. meningitidis infections. Patients can be screened for terminal complement component deficiency by checking CH50.

Complement factor I deficiency: A potentially treatable cause of fulminant cerebral inflammation.

OBJECTIVE: To raise awareness of complement factor I (CFI) deficiency as a potentially treatable cause of severe cerebral inflammation. METHODS: Case report with neuroradiology, neuropathology, and functional data describing the mutation with review of literature. RESULTS: We present a case of acute, fulminant, destructive cerebral edema in a previously well 11-year-old, demonstrating massive activation of complement pathways on neuropathology and compound heterozygote status for 2 pathogenic mutations in CFI which result in normal levels but completely abrogate function. CONCLUSIONS: Our case adds to a very small number of extant reports of this phenomenon associated with a spectrum of inflammatory histopathologies including hemorrhagic leukoencephalopathy and clinical presentations resembling severe acute disseminated encephalomyelitis. CFI deficiency can result in uncontrolled activation of the complement pathways in the brain resulting in devastating cerebral inflammation. The deficit is latent, but the catastrophic dysregulation of the complement system may be the result of a C3 acute phase response. Diagnoses to date have been retrospective. Diagnosis requires a high index of suspicion and clinician awareness of the limitations of first-line clinical tests of complement activity and activation. Simple measurement of circulating CFI levels, as here, may fail to diagnose functional deficiency with absent CFI activity. These diagnostic challenges may mean that the CFI deficiency is being systematically under-recognized as a cause of fulminant cerebral inflammation. Complement inhibitory therapies (such as eculizumab) offer new potential treatment, underlining the importance of prompt recognition, and real-time whole exome sequencing may play an important future role.

Recurrence and Outcomes of Complement-Related Renal Disease After Pediatric Renal Transplantation.

Complement dysregulation is related to different glomerular pathologies. Patients with complement dysregulation have high recurrence risk after transplant; however, with trough-effective therapeutics, renal transplant can be an option for these patients. Here, we present 2 boys with renal disease related to complement dysregulation and their outcomes after renal transplant. Patient 1 had atypical hemolytic uremic syndrome, which was treated with eculizumab before renal transplant; eculizumab therapy was also continued after transplant as preventive therapy. Eculizumab therapy was stopped at year 2 post-transplant. At year 4 post-transplant, his serum creatinine level was 0.87 mg/dL. Patient 2, who had chronic renal disease related to C3 glomerulopathy, was not responsive to eculizumab before renal transplant. At month 4 posttransplant, C3 glomerulopathy recurrence was demonstrated with biopsy, and serum creatinine level was 1.96 mg/dL at this time. Eculizumab was started as a rescue therapy. At year 4 posttransplant, his serum creatinine level was 2.07 mg/dL. In our 2 patients with complement dysregulation, eculizumab was an effective and preventive therapy after renal transplant. However, more studies are needed to understand the long-term efficacy and safety of eculizumab after renal transplant.