Identification and use of biomarkers in Gaucher disease and other lysosomal storage diseases

The value of biomarkers in the clinical management of lysosomal storage diseases is best illustrated by the present use of plasma chitotriosidase levels in the diagnosis and monitoring of Gaucher disease. The enzyme chitotriosidase is specifically produced and secreted by the pathological storage macrophages (Gaucher cells). Plasma chitotriosidase levels are elevated on average 1000-fold in symptomatic patients with Gaucher disease and reflect the body burden on storage cells. Changes in plasma chitotriosidase reflect changes in clinical symptoms. Monitoring of plasma chitotriosidase levels is nowadays commonly used in decision making regarding initiation and optimization of costly therapeutic interventions (enzyme replacement therapy or substrate reduction therapy). A novel substrate has been developed that further facilitates the measurement of chitotriosidase in plasma samples. Moreover, an alternative Gaucher-cell marker, CCL18, has been very recently identified and can also be employed to monitor the disease, particularly in those patients lacking chitotriosidase due to a genetic mutation. There is a need for comparable surrogate markers for other lysosomal storage diseases and the search for such molecules is an area of intense investigation.
Conclusion: The use of biomarkers can provide valuable insight into the molecular pathogenesis of LSDs, such as Gaucher disease and Fabry disease.     

Clinical evaluation of biomarkers in Gaucher disease

Novel or candidate biomarkers require thorough evaluation to establish their utility in a clinical setting. This paper describes an evaluation of several established enzyme markers of Gaucher disease and a newly-described chemokine, pulmonary and activation-regulated chemokine (PARC). The ability of the biomarkers to rank patients with Gaucher disease in order of disease severity and organ bulk, and to reflect changes in key clinical parameters in response to enzyme replacement therapy were evaluated. PARC concentrations were found to be reliably correlated with visceral disease and with key clinical responses to enzyme replacement in an unbiased manner. Unlike chitotriosidase and serum angiotensin-converting enzyme activity, genetic variation in serum PARC did not appear to influence its utility as a biomarker. Conclusion: For each new candidate biomarker of lysosomal storage diseases, a similar clinical evaluation will be required, though the approach will need to be modified according to the clinical features and natural history of each disorder.     

Clinical evaluation of biomarkers in Gaucher disease

Novel or candidate biomarkers require thorough evaluation to establish their utility in a clinical setting. This paper describes an evaluation of several established enzyme markers of Gaucher disease and a newly-described chemokine, pulmonary and activation-regulated chemokine (PARC). The ability of the biomarkers to rank patients with Gaucher disease in order of disease severity and organ bulk, and to reflect changes in key clinical parameters in response to enzyme replacement therapy were evaluated. PARC concentrations were found to be reliably correlated with visceral disease and with key clinical responses to enzyme replacement in an unbiased manner. Unlike chitotriosidase and serum angiotensin-converting enzyme activity, genetic variation in serum PARC did not appear to influence its utility as a biomarker.
Conclusion: For each new candidate biomarker of lysosomal storage diseases, a similar clinical evaluation will be required, though the approach will need to be modified according to the clinical features and natural history of each disorder.     

Biomarkers for lysosomal storage disorders: identification and application as exemplified by chitotriosidase in Gaucher disease

A biomarker is an analyte that indicates the presence of a biological process linked to the clinical manifestations and outcome of a particular disease. An ideal biomarker provides indirect but ongoing determinations of disease activity. In the case of lysosomal storage disorders (LSDs), metabolites or proteins specifically secreted by storage cells are good candidates for biomarkers. Potential clinical applications of biomarkers are found in improved diagnosis, monitoring of disease progression and assessment of therapeutic correction. These applications are illustrated by reviewing the use of plasma chitotriosidase in the clinical management of patients with Gaucher disease, the most common LSD. The ongoing debate on the value of biomarkers in patient management is addressed. Novel analytical methods have revolutionized the identification and measurement of biomarkers at the protein and metabolite level. Recent developments in biomarker discovery by proteomics are described and the future for biomarkers of LSDs is discussed. CONCLUSION: Besides direct applications for biomarkers in patient management, biomarker searches are likely to render new insights into pathophysiological mechanisms and metabolic adaptations, and may provide new targets for therapeutic intervention.     

Gaucher disease: multiple lessons from a single gene disorder

Gaucher disease is the most common lysosomal storage disease. It is caused by a deficiency in the lysosomal enzyme glucocerebrosidase, a beta-glucosidase, which results in the accumulation of the lipid glucocerebroside in macrophages throughout the body. Gaucher disease is most common in the Ashkenazi Jewish population, and three mutations of the gene encoding glucocerebrosidase (GBA) have been shown to be prevalent in this population (c.1226 A > C [N370S], 84GG and IVS2[+1]). In non-Jewish patients, the most common mutation is c.1448 G > C (L444P). Until 15 years ago, treatment has been restricted to symptomatic interventions, such as splenectomy or hip replacement. However, there are now specific treatment options - enzyme replacement therapy and substrate reduction therapy. Future developments may include the use of chaperone therapy.Conclusion: The lessons that we have learned from Gaucher disease may well be applicable to the development of therapies for some of the other less common lysosomal storage diseases.     

Gaucher disease: multiple lessons from a single gene disorder

Gaucher disease is the most common lysosomal storage disease. It is caused by a deficiency in the lysosomal enzyme glucocerebrosidase, a β-glucosidase, which results in the accumulation of the lipid glucocerebroside in macrophages throughout the body. Gaucher disease is most common in the Ashkenazi Jewish population, and three mutations of the gene encoding glucocerebrosidase ( GBA ) have been shown to be prevalent in this population (c.1226 A > C [N370S], 84GG and IVS2[+1]). In non-Jewish patients, the most common mutation is c.1448 G > C (L444P). Until 15 years ago, treatment has been restricted to symptomatic interventions, such as splenectomy or hip replacement. However, there are now specific treatment options – enzyme replacement therapy and substrate reduction therapy. Future developments may include the use of chaperone therapy.
Conclusion: The lessons that we have learned from Gaucher disease may well be applicable to the development of therapies for some of the other less common lysosomal storage diseases.     

Enzyme reconstitution/replacement therapy for lysosomal storage diseases

PURPOSE OF REVIEW: Over the past 15 years, the lysosomal storage diseases have become paradigms for the specific treatment of monogenic disorders, particularly those affecting children. This review summarizes the phenotypes and recent literature regarding enzyme reconstitution (replacement) therapy and outcomes for such treatable lysosomal storage diseases: Gaucher disease, Fabry disease, Pompe disease and the mucopolysaccharidoses. RECENT FINDINGS: Recent clinical trials have shown that enzyme reconstitution therapy effectively treats many of the manifestations of the lysosomal storage diseases. When initiated early in the disease course, enzyme reconstitution therapy can reverse some disease manifestations, but may not completely alleviate the disease progression. Enzyme reconstitution therapy is generally well tolerated. Many adverse events are antibody-related, but can be managed without requiring cessation of enzyme reconstitution therapy. Documented IgE reactions, i.e. anaphylactoid, are quite rare (fewer than 1%). SUMMARY: Enzyme reconstitution therapy is a safe and effective treatment modality available for several of the lysosomal storage diseases. Owing to the short history of enzyme reconstitution therapy, the long-term outcomes of enzyme reconstitution therapy-treated individuals are unknown and require further investigation. Medical professionals must learn to identify patients likely to benefit from these life-changing therapies so as to prevent many of the devastating, irreversible complications of the lysosomal storage diseases.     

Gaucher and Fabry diseases: from understanding pathophysiology to rational therapies

Over the past 40 years there has been remarkable development in our understanding of the pathophysiology of lysosomal storage disorders. This review describes the research carried out on the sphingolipid storage disorders from the first demonstration of the underlying metabolic abnormality in Gaucher disease to the development of enzyme replacement therapy for Gaucher and Fabry diseases. Initial developments in gene therapy are also described. CONCLUSION: The introduction of enzyme replacement therapy has provided a lifeline for patients with Gaucher or Fabry disease. It is anticipated that future developments, including gene therapy, will provide additional therapeutic options.     

Gaucher and Fabry diseases: from understanding pathophysiology to rational therapies

Over the past 40 years there has been remarkable development in our understanding of the pathophysiology of lysosomal storage disorders. This review describes the research carried out on the sphingolipid storage disorders from the first demonstration of the underlying metabolic abnormality in Gaucher disease to the development of enzyme replacement therapy for Gaucher and Fabry diseases. Initial developments in gene therapy are also described.
Conclusion : The introduction of enzyme replacement therapy has provided a lifeline for patients with Gaucher or Fabry disease. It is anticipated that future developments, including gene therapy, will provide additional therapeutic options.     

Enzyme replacement therapy: from concept to clinical practice

In the early 1960s, the first lysosomal storage disease was identified. Since then over 40 such diseases have been reported. The common feature is that enzyme deficiency leads to accumulation of undegraded macromolecules and lysosomal engorgement, resulting in organ dysfunction. Enzyme replacement therapy (ERT) is being developed for many of these disorders. The present paper summarizes the history of the development of ERT, with particular reference to the mucopolysaccharidoses, and specifically, to mucopolysaccharidosis type VII (MPS VII). The rarity of MPS VII has meant that ERT is not yet available for the small number of affected patients, although the study of MPS VII and murine models of the disease have played an important part in the development of treatment for related disorders, including Gaucher disease.
Conclusion : Much progress has been made in our understanding of lysosomal storage diseases over the past 40 years. This has led to the development of effective ERT for some of the more common storage diseases, such as Fabry disease and Gaucher disease. Treatment is still awaited, however, for many of the other rare disorders in this area, such as MPS VII.     

Individualized long‐term enzyme therapy for Gaucher disease type 1 in Slovenia

Background: Gaucher disease type 1 (GD1) was the first lysosomal storage disorder for which an effective enzyme replacement therapy was developed. We describe the management of eight GD1 patients in Slovenia who were diagnosed between the ages of 2 and 15 years. Methods: Patients were individually assessed to establish initial enzyme doses and monitored frequently to determine the effects of long‐term enzyme dose regimens. Outcomes up to 10 years after long‐term treatment are described by changes in the Zimran severity score index, chitotriosidase and acid phosphatase levels, and after 2001, bone parameters (DEXA bone mineral density scores and the MRI bone marrow burden score). Results: Following the initiation of enzyme therapy with individualized dose regimens (range 25–56 U/kg/14 days) and followed by a gradual reduction of doses (range 12–35 U/kg/14 days) during long‐term maintenance, disease status improved in all patients as measured by the Zimran severity score index (from a mean of 11.25 [median 11.5] before therapy to a mean of 4.12 [median 3.5] at last report). Anemia and leucopenia resolved in all patients, chitotriosidase and acid phosphatase levels decreased in all patients (and by over 75% in six patients) within 1 year of treatment. Bone marrow burden scores improved in all monitored patients and DXA scores improved in six of seven monitored patients. Conclusions: We conclude that enzyme therapy with relatively low, individualized dose regimens is well‐tolerated and effective in children and young adults with GD1 disease, who are regularly monitored for changes in disease status.     

Gaucher disease: unmet treatment needs

Gaucher disease is a multisystemic metabolic disorder arising from a deficiency of lysosomal glucocerebrosidase. The predominant clinical manifestations of the disease are hepatosplenomegaly, peripheral blood cytopenias and skeletal disease. Treatment with enzyme replacement therapy (ERT) and substrate reduction therapy (SRT) has been shown to be effective in improving organ volume, anaemia, thrombocytopenia, bone markers and biomarkers in patients with Gaucher disease. However, some patient needs remain unmet because of the limited availability of treatment, the inaccessibility of certain disease sites and emerging disease manifestations. An increase in haematological, lymphoreticular and immune system malignancies has been observed in patients with Gaucher disease, but mechanisms underlying the development of these are not fully understood. Mild neurological manifestations may also affect patients with type 1 Gaucher disease, but treatment with ERT or SRT does not improve neurological function. Potential new treatments for Gaucher disease include small molecules, which may penetrate tissues that are not accessible by ERT. CONCLUSION: ERT currently remains the most effective treatment for Gaucher disease. New treatments are emerging, but deficiencies in understanding basic pathophysiological mechanisms hinder progress.     

Enzyme replacement therapy: from concept to clinical practice

In the early 1960s, the first lysosomal storage disease was identified. Since then over 40 such diseases have been reported. The common feature is that enzyme deficiency leads to accumulation of undegraded macromolecules and lysosomal engorgement, resulting in organ dysfunction. Enzyme replacement therapy (ERT) is being developed for many of these disorders. The present paper summarizes the history of the development of ERT, with particular reference to the mucopolysaccharidoses, and specifically, to mucopolysaccharidosis type VII (MPS VII). The rarity of MPS VII has meant that ERT is not yet available for the small number of affected patients, although the study of MPS VII and murine models of the disease have played an important part in the development of treatment for related disorders, including Gaucher disease. CONCLUSION: Much progress has been made in our understanding of lysosomal storage diseases over the past 40 years. This has led to the development of effective ERT for some of the more common storage diseases, such as Fabry disease and Gaucher disease. Treatment is still awaited, however, for many of the other rare disorders in this area, such as MPS VII.     

Substrate reduction therapy

The therapeutic options for lysosomal storage diseases (LSDs) have expanded greatly over the past decade, although for many disorders there is still no effective treatment. Given that the majority of LSDs involve pathological changes in both the brain and peripheral tissues, effective treatment of central nervous system (CNS) and peripheral manifestations still remains a considerable technical challenge. Type 1 Gaucher disease has two approved treatment modalities - enzyme replacement therapy (ERT) and substrate reduction therapy (SRT) - which have unique, independent and potentially complementary mechanisms of action. The availability of these two therapies has greatly increased the options for the effective clinical management of type 1 Gaucher disease. ERT involves the intravenous administration of fully functional enzyme that is taken up by cells and delivered to the lysosome, where it can compensate for the underlying enzyme deficiency. SRT uses an orally available, small molecule drug that inhibits the first committed step in glycosphingolipid biosynthesis. The aim is to reduce the rate of biosynthesis of glycosphingolipids to offset the catabolic defect, restoring the balance between the rate of biosynthesis and the rate of catabolism. SRT also has the potential to treat LSDs with CNS pathology, as the drug in clinical use (miglustat, Zavesca; Actelion Pharmaceuticals Ltd, Allschwil, Switzerland) crosses the blood-brain barrier. In this review, the current status of SRT for the treatment of Gaucher disease and other LSDs will be discussed, based upon preclinical and clinical studies. CONCLUSION: SRT is an oral alternative treatment option for patients with type 1 Gaucher disease unwilling or unable to receive ERT. With the recent reports of clinical improvement/stabilization of CNS manifestations following SRT in patients with Niemann-Pick disease type C, miglustat may also have a role to play in the management of patients with glycosphingolipid storage in the brain. Furthermore, as SRT synergises with other therapeutic modalities, it may also prove to be a key component of combination therapies in the future.     

Allogenic bone marrow transplantation in severe Gaucher disease.

Gaucher disease is the most prevalent lysosomal storage disease. This autosomal recessive disease is caused by the defective activity of the enzyme acid beta-glucosidase and the resultant accumulation of glucosylceramide primarily within cells of the reticuloendothelial system. Because the primary manifestations of Gaucher disease are due to involvement of monocyte/macrophage-derived cells, this disease is thought to be an excellent candidate for curative intervention via bone marrow transplantation (BMT). A Hispanic female with subacute neuronopathic Gaucher disease and rapidly progressing visceral manifestations underwent BMT at 23 mo of age using her histocompatible normal brother as the donor. Cytogenetic analyses demonstrated complete, stable engraftment by 1 mo post-BMT. During the subsequent 24 mo, clinical, biochemical, enzymatic, and histologic studies demonstrated nearly complete correction in the viscera. Her neuropathic manifestations did not progress. Complete reconstitution of enzymatic activity in peripheral blood leukocytes was achieved by 1 mo. Cytogenetic analyses demonstrated complete engraftment by d 79 and nearly complete loss of bone marrow Gaucher cells was observed by 8 mo. Plasma glucosylceramide levels normalized by 8-12 mo. Nearly coincident improvements in hepatic size, enzyme levels, and histology were found by 12-24 mo post-BMT. Fatal sepsis occurred at 24 mo post-BMT. Autopsy revealed sparse Gaucher cells in clusters in the liver, lymph nodes, and lungs as well as the lack of periadventitial Gaucher cells surrounding brain vessels. The findings provide the time course and rationale for studies directed to gene therapy via BMT for this disease after introduction of acid beta-glucosidase gene constructs into autologous pluripotent stem cells of selected Gaucher disease patients.     

Le traitement par enzymothérapie des maladies lysosomales

In the last years, much progress has been achieved in the treatment of lysosomal storage disorders. Until recently only symptomatic treatment was available for the affected patients. Progressively enzyme replacement treatments have been developed for several diseases, namely Gaucher disease, Fabry disease, mucopolysaccharidoses type I, II and VI and Pompe disease. In this review we will summarize the efficacy and safety of these treatments and describe new therapeutic trials for other lysosomal storage disorders or perspectives in the use of currently available treatments.     

Biomarkers in lysosomal storage diseases: a review

A biomarker is generally an analyte that indicates the presence or extent of a biological process, which is itself directly linked to the clinical manifestations and outcome of a particular disease. An ideal biomarker provides indirect but ongoing and specific determinations of disease activity. These characteristics emphasize the value of surrogate biomarkers for non-invasive and detailed monitoring to demonstrate the efficacy of orphan drugs in clinical trials. The emergence of novel laboratory methods has facilitated the search for biomarkers in lysosomal storage diseases (LSDs), by allowing the systematic identification of molecules whose expression is altered as a result of the primary storage pathology. In Gaucher disease, for example, a chemokine, CCL18, has been identified as a biomarker for clinical development that reflects disease severity and response to treatment.
Conclusion: New methods for the identification of novel biomarkers have the potential to provide mechanistic insights into the molecular pathogenesis of LSDs, including Fabry disease and Gaucher disease.     

Biomarkers in lysosomal storage diseases: a review

A biomarker is generally an analyte that indicates the presence or extent of a biological process, which is itself directly linked to the clinical manifestations and outcome of a particular disease. An ideal biomarker provides indirect but ongoing and specific determinations of disease activity. These characteristics emphasize the value of surrogate biomarkers for non-invasive and detailed monitoring to demonstrate the efficacy of orphan drugs in clinical trials. The emergence of novel laboratory methods has facilitated the search for biomarkers in lysosomal storage diseases (LSDs), by allowing the systematic identification of molecules whose expression is altered as a result of the primary storage pathology. In Gaucher disease, for example, a chemokine, CCL18, has been identified as a biomarker for clinical development that reflects disease severity and response to treatment. Conclusion: New methods for the identification of novel biomarkers have the potential to provide mechanistic insights into the molecular pathogenesis of LSDs, including Fabry disease and Gaucher disease.     

Coagulation abnormalities in type 1 Gaucher disease in children

Gaucher disease is the most prevalent inherited lysosomal storage disorder caused by deficiency of β-glucocerebrosidase enzyme. Clinically, 3 forms of Gaucher disease are recognized, of which type 1 is the mild to moderately severe, slowly progressive, nonneuropathic form. Bleeding disorders in Gaucher disease are believed to be due to thrombocytopenia but there may be additional factors that influence coagulation and fibrinolysis in Gaucher disease patients. The aim of the present work was to study some coagulation parameters in the Egyptian children with type 1 Gaucher disease. Five newly diagnosed patients and another 5 patients on enzyme replacement therapy (ERT) were enrolled in the study. Their coagulation profile, including coagulation factors, was evaluated. The results showed that in newly diagnosed cases factors II and VII were deficient in 40%, factor V was deficient in 20%, and all the cases had low levels of serum fibrinogen. In patients on ERT, factors VII and VIII were deficient in 60%, factor XI was deficient in 40% and factors V, X, and XII were deficient in 20% of cases. In conclusion, Egyptian patients with type 1 Gaucher disease, whether newly diagnosed or receiving enzyme replacement therapy, experience coagulation factor abnormalities regardless the clinical expression of bleeding diathesis. This should be taken into consideration before these patients are subjected to surgery for, e.g., splenectomy, which is common in these patients.     

Substrate reduction therapy for lysosomal storage diseases

The treatment of disordered lipoprotein metabolism with the statin class of drugs is one of the most striking successes in the field of applied medical science: here the use of selective inhibitors of the first committed step of cholesterol biosynthesis, in a complex and highly regulated pathway, leads to improved outcome from a common lipid storage disease that is a blight on whole populations--atherosclerosis. By the same token, substrate reduction is an emerging therapeutic strategy for the arcane field of the lysosomal storage diseases (LSDs). Reduced biosynthesis of glucosylceramide is postulated to allow correction of the imbalance between formation and breakdown of glycosphingolipids; the therapeutic effect of substrate reduction depends upon the presence of residual hydrolytic activity towards those accumulated glycosphingolipid substrates derived from glucosylceramide. First pioneered in the laboratory by Norman Radin, this approach has now been introduced into the clinic: based on the ability to inhibit uridine diphosphate glucosylceramide transferase, the semi-selective iminosugar, N-butyldeoxynojirimycin, is licensed for the treatment of type 1 Gaucher disease. Conclusion: Inhibition of substrate formation has wide application in the treatment of LSDs. Decreased glucosylceramide biosynthesis has therapeutic potential in glycosphingolipidoses other than Gaucher disease, and offers promise in several neurodegenerative storage disorders that are currently beyond the reach of other procedures. The results of ongoing clinical trials of miglustat in type 3 Gaucher disease, Niemann-Pick disease type C and GM2 gangliosidosis are eagerly awaited.