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. Author manuscript; available in PMC: 2013 Dec 1.
Published in final edited form as: Ann N Y Acad Sci. 2012 Dec;1275(1):101–106. doi: 10.1111/j.1749-6632.2012.06787.x

Biomarker development for myasthenia gravis

Henry J Kaminski 1,2, Linda L Kusner 2, Gil I Wolfe 3, Inmaculada Aban 4, Greg Minisman 4, Robin Conwit 5, Gary Cutter 4
PMCID: PMC3539232  NIHMSID: NIHMS410090  PMID: 23278584

Abstract

Biomarkers are defined as characteristics (proteins, RNA, single nucleotide polymorphisms, imaging) that are objectively measured and evaluated as an indicator of pathogenic processes or pharmacologic responses to a therapeutic intervention. Biomarkers are important in clinical trials where the robust biomarker reflects the underlying disease process in a sensitive and reliable manner. For myasthenia gravis (MG), acetylcholine receptor and muscle specific kinase antibodies, as well as single fiber electromyography, serve as excellent biomarkers for diagnosis but do not adequately substitute for clinical evaluations to predict treatment response. New technologies are emerging that enable broad biomarker discovery in biological fluids. Biomarker evaluation is ideally done in the context of longitudinal clinical trials. The MGTX trial has collected plasma and serum for RNA and protein analysis and thymus, which will allow robust biomarker discovery. The ultimate goal will be to identify candidates for a reliable substitute for a clinically meaningful endpoint that is a direct measure of the effectiveness of a therapy in the context of a continuum of disease natural history and a patient's overall well-being.

Keywords: biomarkers, myasthenia gravis, surrogate endpoint, Prentice criteria

The Food and Drug Administration (FDA), National Institutes of Health, and the pharmaceutical/device maker industry have placed a major focus on the identification of biomarkers to assist therapeutic development in preclinical and early phase studies on humans1, 2. Why? Despite some remarkable success in discovery of novel treatments, therapeutic development has a high failure rate 35. Numerous forces are now driving limitations on financial support for discovery of new treatments, whether scientists work in the private or public sector. Biomarkers in animal studies, which support efficacy in humans and ones that can robustly support go-no go decisions in preliminary clinical trials, offer promise to decrease the failure rate, shorten the duration, and thereby reduce the cost of therapeutic development.

Biomarker categorization

The FDA of the United States defines biomarkers as characteristics that are objectively measured and evaluated as indicators of normal biologic processes, pathogenic activity, or pharmacologic responses to a therapeutic intervention 6. Biomarkers may be assessed by a variety of measures from biological specimens, such as molecular genetic characteristics, histology, and serum proteins as well as imaging evaluations. Several varieties of biomarkers exist (Table 1). For example, prognostic biomarkers sort patients according to the likely course of disease (if left untreated), while predictive biomarkers identify subpopulations of patients who are likely to respond to a specific therapy. The drug dosage for responsive individuals is optimized by analysis of pharmacodynamic biomarkers. Biomarkers may predict or identify safety problems related to a therapeutic candidate. In some circumstances, a biomarker may identify a patient population subgroup that becomes the focus for specific clinical trials. These include prognostic biomarkers that identify patients with a disease risk most suitable for an efficient drug development program. In other circumstances, a predictive biomarker may identify a patient subgroup that has a greater potential to benefit from the mechanism of action of the specific drug or a lower risk of an identified adverse effect of the drug. As with any measure, there are variability and specificity issues that must be considered for each specific application. The rigor of the validation process for a biomarker is dependent on its ultimate clinical use.

Table 1.

Categorization of biomarkers

Biomarker Example Disease
Diagnostic Elevated fasting blood sugar
Acetylcholine receptor and muscle specific antibody		 Diabetes mellitus
Myasthenia gravis
Disease Extent/severity Lesion burden on magnetic resonance imaging
Tumor size		 Multiple sclerosis
Various neoplasms
Pharmacodynamic, marker Serum cyclo-oxygenase (COX)-2 inhibition Pain relief
Prognostic marker Estrogen receptor status Breast cancer
Predictive marker Serum cholesterol
Blood pressure		 Cardio- and cerebrovascular disease
Drug characterization Complement inhibition (by drug eculizumab) Paroxysmal hemaglobinuria
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The surrogate endpoint is of greatest interest for therapeutic development, and their validation as a predictor of efficacy requires fulfillment of strict criteria. The surrogate endpoint is intended to substitute for a primary clinical endpoint and is expected to predict a clinical benefit, lack of benefit, or harm as would the gold standard clinical endpoint. Prentice originally proposed criteria to define expectations for a surrogate (Table 2). To act as a surrogate endpoint a biomarker must fulfill these properties, which are ideally assessed in the context of a clinical trial 7. Of course, this also assumes that clinical efficacy evaluations have been validated appropriately, which is also a challenge. Only in the case of death as a clinical end point can one consider the clinical measures to be unequivocal.

Table 2.

Prentice Criteria for Surrogate Endpoint Validation

Treatment must have an effect on the surrogate
Treatment must have an effect on the clinical outcome
Surrogate and the clinical outcome must be correlated
Treatment effect on the true clinical outcome must disappear when adjusting for the surrogate
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Biomarkers in myasthenia gravis

The MG research field lags behind other areas of medicine in the development of biomarkers, and existing biomarkers are severely limited in their ability to predict a response to treatment, assess susceptibility to adverse effects of treatment, or correlate with disease severity. This lack of validated biomarkers is a glaring deficiency for therapeutic development for MG, especially when novel treatments are being considered for application. This state is all the more surprising because MG is one of the best characterized autoimmune disorders from a biological perspective and is among the few that fulfills strict criteria for autoimmunity.

Biomarkers that presently exist in MG fall primarily in the diagnostic category. Detection of acetylcholine receptor (AChR) or muscle specific kinase (MuSK) antibodies is highly specific for confirming the diagnosis of MG; however, their absolute levels do not correlate with disease severity 810. Although levels of AChR and MuSK antibodies tend to fall with treatment, this is highly variable and does not correlate well with disease severity or clinical response. The therapeutic usefulness of biomarkers in guiding treatment decisions is illustrated by the identification of MuSK antibodies, which correlate with poor response to cholinesterase inhibitor treatment and often predict refractoriness to other treatment approaches. However, such observations have been drawn from retrospective analyses.

The MG Foundation of America Task Force for evaluation of clinical endpoints, of which three of the authors (HK,GW,GC) were members, reviewed potential biomarkers used in MG. None fulfill criteria sufficiently to serve as surrogate endpoints. Acetylcholine receptor (AChR) antibody titers have been used as a marker for therapeutic response 1113, but there is no basis to use them as a potential substitute for a clinical outcome measure. Single fiber EMG, in expert hands, appears to correlate well to clinical state; however, it is of limited use as a predictor of of clinical outcome, especially due to the likelihood of significant inter-observer variability14. Of relevance to MG treatment is the thiopurine S-methyltransferase activity or identification of the TPMT gene mutation as a marker of toxicity for azathioprine use.15

Genetic markers may one day serve as biomarkers important for therapeutic targeting. A genetic association for MG is supported 16 by: 1) MG occurrence in up to 4% of family members of patients with MG, while the risk of generalized MG in the population is 0.01%; 2) twin studies showing a heritability index of 0.65, a level that places MG in the range of Alzheimer's disease and epilepsy and above multiple sclerosis for genetic predisposition; 3) HLA-B8 and DR3 alleles are increased in patients with MG when compared with the general population; 4) The MYSA1 locus is associated with MG and thymic hyperplasia. MYSA1 lies within the central region of the HLA region and the biological basis for it leading to susceptibility to MG has not been determined; 5) linkage dysequilibrium analysis identified an association with a marker in the CHRNA1 gene, which codes for the alpha subunit of the ACHR, that has been closely associated with MG; 6) and a polymorphism identified in the promoter region of the decay accelerating factor (DAF) gene, a complement regulator associated with a severe form of MG that produces irreversible ophthalmoparesis17.

Preclinical evaluation

Development of therapeutics is dependent on exploratory evaluations in animals, and the field of MG benefits greatly from the existence of robust animal models. Patrick and Lindstrom demonstrated that immunization of rabbits with purified acetylcholine receptor leads to development of disease that mimics the human disorder 18. Subsequent studies have demonstrated that experimental autoimmune MG (EAMG) can be induced in several mammalian species by immunization with AChR of mammals, the electric organ of eels or rays, and peptide fragments of AChR subunits 19. These models reproduce aspects of human MG, including a breakdown in tolerance with production of autoantibodies, the neuromuscular transmission defect, response to anti-cholinesterase therapy, and moderation of the disease by treatments used in patients. EAMG produced by administration of antibodies to the acetylcholine receptor fails to mimic the breakdown in tolerance and induces significant inflammation, which is not present in muscles of patient, but does mimic the final common pathway of injury to the neuromuscular junction that occurs in humans, and therefore, also serves as an appropriate model to evaluate certain therapeutics. These models have been used to delineate autoimmune mechanisms and to evaluate therapeutics 20, 21 but to date have not been a focus for biomarker discovery.

Because of inherent differences between humans and animals, no animal model, thus far, fully mimics the human disease. Despite common features of mammalian immune systems, there are differences in basic regulatory proteins of human, mouse and rat systems. EAMG differs from human MG in the need to administer exogenous and repeated antigenic stimulation to produce and maintain disease. Fluctuations of weakness and autoimmune activity are not observed over time. Therefore, caution is necessary when extrapolating positive results from animals to humans. This is not just a problem for MG. A glaring example is over 300 preclinical studies of Alzheimer's disease suggesting efficacy of therapy in mouse models, none of which have led to a therapeutic effect in humans 22. Therefore, there is a great need for biomarker discovery to be integrated coherently into both preclinical and clinical efforts. The long term benefit that would result from validated markers of efficacy in humans would be enormous. And if these discoveries have parallels in animal studies the potential to translate novel treatments from preclinical studies to the bedside would be far more efficient. Of course, there is also benefit in the early termination of preclinical efforts that have little chance for success in order to save the hundreds of millions of dollars that are expended on human early phase trials.

MGTX study and biomarker discovery opportunity

In 2005 the National Institutes of Health funded a multicenter, international, single-blinded, randomized trial (MGTX) to determine whether extended transsternal thymectomy for patients receiving the prednisone protocol confers added benefits to the prednisone protocol alone 23, 24. As part of the investigation, an ancillary study was supported with the intent to collect thymus, plasma, serum and blood-derived RNA with the intent of developing the first biomarker discovery assessment in the history of MG. As of this writing, 82 subjects have provided blood specimens at baseline and 6-month follow-up with collection ongoing at 1, 2, and 3 years post randomization. Over 50 thymic specimens have been collected, and analysis for histological evaluation has demonstrated good to excellent quality of specimen integrity. The opportunity exists now to launch a state-of-the-art, unbiased biomarker discovery program utilizing these specimens. To that end, the authors are moving toward the use of independent -omics assays (proteomics, microRNA, RNA profiling, metabolomics) coupled with antigen-specific IgG subclass definition on samples obtained through MGTX and to perform similar analyses on samples obtained from mice with EAMG. Below we briefly describe the methods to be used.

Nanoparticle proteomics

Body fluids such as serum represent a valuable source of biomarker information. Identification and monitoring of circulating biomarkers enable early disease detection, disease/morbidity risk stratification, and help assess disease progression and thus responsiveness to interventions 25. Despite recent progress in the field of proteomics, identification of novel plasma biomarkers such as proteins has been difficult due to low quantities relative to larger and more abundant plasma proteins, such as albumin 26. Nanoparticle proteomic technology will allow identification and quantitation of less abundant proteins within patient samples.

MicroRNA profiling

Micro RNA (miRNA) has emerged as a new and important class of cellular regulators. Experimental studies have provided strong evidence that aberrant expression of miRNA is associated with a broad spectrum of human diseases, including cancer, diabetes, and cardiovascular and psychological disorders. The relatively small numbers of miRNAs discovered in humans (~800 miRNAs, miRBase12.0) are involved in regulation of a large number of human genes (up to 80% of known genes). miRNAs have exceptional potential as biomarkers because of their relative abundance, highly specific expression, and stable presence in serum and plasma. In fact, circulating miRNAs demonstrate reasonable sensitivity in a small number of Duchenne muscular dystrophy patients as biomarkers for disease progression and severity and also correlate with circulating miRNA in mice with dystrophin deficiency 27.

Metabolomics profiling

Metabolomics is a rapidly developing field that aims to identify and quantify the concentration changes of all the metabolites (i.e., the metabolome) in a given biofluid from a subject and support targeting and developing therapeutics 28. The anticipated contribution of metabolomics to the field of science and to health care is highlighted by its presence in the current NIH Roadmap. The application of metabolomics to understand the manifestation and progression of complex neurological diseases represents a powerful means to identify the earliest markers associated with disease progression and treatment response.

MG-focused assessments

The final effector mechanism in most patients withMG is the AChR antibody 29. A fundamental challenge for the MG field is that the level of the autoantibody does not correlate with disease severity. Numerous investigations have demonstrated that there is a significant role of complement as a driver of disease pathology in experimental animals and humans with MG. In concert with the broad-based assessments, we will specifically evaluate IgG subclasses, that are specific to the human AChR autoantigen. It is also well appreciated that cytokines regulate the cell responses of the immune system; multiplex cytometric bead assays can be used to measure levels of serum cytokines 30 to determine the treatment effect on these biomarkers, although these may be too volatile to be used as effective biomarkers.

Identification is not enough

Identifying putative biomarkers is a major endeavor in all diseases in the era of personalized medicine, but the challenge in establishing a biomarker should not be underestimated. The Prentice criteria are theoretical and have not been achieved even where biomarkers are felt to exist (e.g., blood pressure for cardiovascular disease or CD4 counts for HIV). Although the path to validation of a biomarker is long and arduous, the payoff is enormous for patients, the field of research, and is now a reasonable undertaking with the tools that are at hand.

Conclusion

The time has come for further breakthroughs in treatment of MG. The only path forward lies in exploiting approaches that the field of cancer therapeutics are beginning to leverage. These include rigorously evaluated clinical endpoints and identification of biomarkers for subcategorization of neoplasms on a molecular level indicative of potential therapeutic targets in clinical trials. One such success story is that of chronic myelogenous leukemia which began with discovery of the Philadelphia chromosome and finally led to targeting an antibody to inhibit a tyrosine kinase 31. The drug developed is Gleevec, a highly effective treatment for this subset of leukemia patients. MG faces particular challenges in that universally accepted clinical endpoints have only recently been rigorously defined 32, 33 and research consortiums to perform robust clinical trials are only a decade old. The field also faces the challenge of a lack of investigators trained in biomarker discovery. However, it is expected the MGTX supported biological specimen bank will offer many investigators a unique opportunity to move the field forward for the benefit of generations of patients to come.

Acknowledgments

This work was supported by NINDS Grant U01 NS042685.

Footnotes

Conflicts of interest

The authors declare no conflicts of interest

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