For two years, four investigators will each hire a new full-time employee to identify and validate a novel therapeutic strategy for a group of rare inherited metabolic disorders, the Congenital Disorders of Glycosylation-Type I (CDG-I). These disorders result in underglycosylation of proteins and associated multisystem pathologies, morbidity, and mortality are common since the vast majority of CDG-I patients cannot be treated. Currently, 13 Type-I CDGs are clinically and genetically defined. Most have deficiencies in transferases and substrates necessary to synthesize the precursor of N-linked glycoproteins, glucose3mannose9GlcNAc2-P-P-dolichol, also known as """"""""lipid-linked oligosaccharide"""""""" or """"""""LLO"""""""". These deficiencies result in underglycosylation of proteins and associated multi-system pathologies, morbidity, and mortality. In many CDG-I patients, the primary defect impairs mannose metabolism. CDG-I patients all have hypomorphic alleles, and we propose to take advantage of the residual enzyme activities by a novel therapeutic strategy we term """"""""substrate-flux"""""""". For example, in CDG-Ia (the most common form of CDG), we will use various chemical agents to """"""""coax"""""""" more of the patients'own limited metabolite pool (in this case mannose- 6-phosphate) toward the defective enzyme (phosphomannomutase), divert the pool away from competing enzymes (mannose phosphate isomerase), and/or alter associated pathways (providing dolichol-P or regulating protein synthesis) so that the limited substrate pool is used more effectively. Our research team has three known drugs and five experimental compounds in-hand, all of which have given promising results in preliminary cell culture experiments and are ready for animal testing. However, a severe limitation of CDG research is the absence of representative animal models. Knockout mice are embryonic lethal and although CDG-gene hypomorphic mice are just now emerging, they are not yet ready as a model to evaluate therapies. Thus, to test substrate-flux therapy immediately, we are harnessing the power and speed of zebrafish genetics to generate new vertebrate CDG-I zebrafish models with morpholino oligonucleotides (essentially a """"""""knockdown"""""""" approach). These are being validated both pathologically and biochemically. Recent preliminary data support the successful generation of pmm2 morphant zebrafish as a model of CDG-Ia;they have an appropriate LLO defect and phenotypes recapitulating aspects of CDG patients. Positive drug results with zebrafish models will rapidly determine whether flux-altering agents affect CDG-I phenotypes, and will then be confirmed with authentic CDG-I patient cell cultures. Concurrent with these studies, the mechanisms of the agents in question will be tested directly by mannose flux experiments in both normal and CDG-I human cell cultures and zebrafish models. Efficacious compounds are confirmed by flux studies in normal mice. Screening of the next generation of flux-enhancing molecules is underway. Within two years, we will identify fluxmodifying agents and demonstrate real potential for CDG treatment. At this point the known drugs would be appropriate for off-label clinical evaluation, and the experimental drugs will then be tested in emerging mouse models of CDG-I.

Public Health Relevance

Very few patients with """"""""Congenital Disorders of Glycosylation"""""""" (CDG) can be successfully treated. These patients suffer multi-system pathology, morbidity, and mortality because they do not glycosylate proteins normally. Our four-investigator team will hire four scientific staff to test a new treatment strategy called """"""""substrate-flux"""""""" therapy. Since mouse models do not yet exist we will evaluate therapy in a series of novel zebrafish CDG models that we've created.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
NIH Challenge Grants and Partnerships Program (RC1)
Project #
1RC1HD064159-01
Application #
7842801
Study Section
Special Emphasis Panel (ZRG1-BDA-A (58))
Program Officer
Oster-Granite, Mary Lou
Project Start
2009-09-30
Project End
2011-08-31
Budget Start
2009-09-30
Budget End
2010-08-31
Support Year
1
Fiscal Year
2009
Total Cost
$499,994
Indirect Cost
Name
Sanford-Burnham Medical Research Institute
Department
Type
DUNS #
020520466
City
La Jolla
State
CA
Country
United States
Zip Code
92037
DeRossi, Charles; Vacaru, Ana; Rafiq, Ruhina et al. (2016) trappc11 is required for protein glycosylation in zebrafish and humans. Mol Biol Cell 27:1220-34
Vacaru, Ana M; Unlu, Gokhan; Spitzner, Marie et al. (2014) In vivo cell biology in zebrafish - providing insights into vertebrate development and disease. J Cell Sci 127:485-95
Chu, Jaime; Mir, Alexander; Gao, Ningguo et al. (2013) A zebrafish model of congenital disorders of glycosylation with phosphomannose isomerase deficiency reveals an early opportunity for corrective mannose supplementation. Dis Model Mech 6:95-105
Howarth, Deanna L; Yin, Chunyue; Yeh, Karen et al. (2013) Defining hepatic dysfunction parameters in two models of fatty liver disease in zebrafish larvae. Zebrafish 10:199-210
Cline, Abigail; Gao, Ningguo; Flanagan-Steet, Heather et al. (2012) A zebrafish model of PMM2-CDG reveals altered neurogenesis and a substrate-accumulation mechanism for N-linked glycosylation deficiency. Mol Biol Cell 23:4175-87
Freeze, Hudson H; Sharma, Vandana (2010) Metabolic manipulation of glycosylation disorders in humans and animal models. Semin Cell Dev Biol 21:655-62