Table Of ContentAtlAs of
InherIted
MetAbolIc
dIseAses
AtlAs of
InherIted
MetAbolIc
dIseAses
thIrd edItIon
William L Nyhan, MD PhD
Professor of Pediatrics
Biochemical Genetics Program
University of California, San Diego
USA
Bruce A Barshop, MD PhD
Professor of Pediatrics
Biochemical Genetics Program
University of California, San Diego
USA
and
Aida I Al-Aqeel, MD DCH FRCP FACMG
Consultant and Head Pediatrics, Medical Genetics and Consultant Endocrinology
Riyadh Military Hospital
Riyadh
Saudi Arabia
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Contents
Contributor� ix
Foreword� xi
Preface� xii
Part 1 Organic acidemias
��1� Introduction� 3
��2� Propionic�acidemia� 8
��3� Methylmalonic�acidemia� 19
��4� Methylmalonic�aciduria�and�homocystinuria�(cobalamin�C�and�D�disease)� 33
��5� Multiple�carboxylase�deficiency/holocarboxylase�synthetase�deficiency� 40
��6� Multiple�carboxylase�deficiency/biotinidase�deficiency� 47
��7� Isovaleric�acidemia� 57
��8� Glutaric�aciduria�(type�I)� 64
��9� 3-Methylcrotonyl�CoA�carboxylase�deficiency/3-methylcrotonyl�glycinuria� 74
�10� D-2-Hydroxyglutaric�aciduria� 79
�11� L-2-Hydroxyglutaric�aciduria� 85
�12� 4-Hydroxybutyric�aciduria� 89
�13� Mitochondrial�acetoacetyl-CoA�thiolase�(3-oxothiolase)�deficiency� 95
Part 2 disOrders Of aminO acid metabOlism
�14� Alkaptonuria� 105
�15� Phenylketonuria� 112
�16� Hyperphenylalaninemia�and�defective�metabolism�of�tetrahydrobiopterin� 123
�17� Biogenic�amines� 136
�18� Homocystinuria� 144
�19� Maple�syrup�urine�disease�(branched-chain�oxoaciduria)� 152
�20� Oculocutaneous�tyrosinemia/tyrosine�aminotransferase�deficiency� 164
�21� Hepatorenal�tyrosinemia/fumarylacetoacetate�hydrolase�deficiency� 171
�22� Nonketotic�hyperglycinemia� 180
Part 3 HyPerammOnemia and disOrders Of tHe urea cycle
�23� Introduction�to�hyperammonemia�and�disorders�of�the�urea�cycle� 191
�24� Ornithine�transcarbamylase�deficiency� 197
�25� Carbamylphosphate�synthetase�deficiency� 205
�26� Citrullinemia� 210
�27� Argininosuccinic�aciduria� 216
�28� Argininemia� 223
�29� Hyperornithinemia,�hyperammonemia,�homocitrullinuria�syndrome� 229
�30� Lysinuric�protein�intolerance� 235
�31� Glutamine�synthetase�deficiency� 241
vi Contents
Part 4 disOrders Of fatty acid OxidatiOn
�32� Introduction�to�disorders�of�fatty�acid�oxidation� 247
�33� Carnitine�transporter�deficiency� 253
�34� Carnitine-acylcarnitine�translocase�deficiency� 260
�35� Carnitine�palmitoyl�transferase�I�deficiency� 267
�36� Carnitine�palmitoyl�transferase�II�deficiency,�lethal�neonatal� 273
�37� Carnitine�palmitoyl�transferase�II�deficiency,�late�onset� 277
�38� Medium�chain�acyl�CoA�dehydrogenase�deficiency� 281
�39� Very�long�chain�acyl�CoA�dehydrogenase�deficiency� 289
�40� Long�chain�L-3-hydroxyacyl�CoA�dehydrogenase�–�(trifunctional�protein�deficiency)� 295
�41� Short-chain�acyl�CoA�dehydrogenase�deficiency� 302
�42� 3-HydroxyacylCoA�dehydrogenase�(short-chain�3-hydroxyacylCoA�dehydrogenase)�deficiency� 309
�43� Short/branched�chain�acyl-CoA�dehydrogenase�(2-methylbutyrylCoA�dehydrogenase)�deficiency� 312
�44� Multiple�acyl�CoA�dehydrogenase�deficiency/glutaric�aciduria�type�II/ethylmalonic-adipic�aciduria� 316
�45� 3-Hydroxy-3-methylglutarylCoA�lyase�deficiency� 325
Part 5 tHe lactic acidemias and mitOcHOndrial disease
�46� Introduction�to�the�lactic�acidemias� 337
�47� Pyruvate�carboxylase�deficiency� 347
�48� Fructose-1,6-diphosphatase�deficiency� 354
�49� Deficiency�of�the�pyruvate�dehydrogenase�complex� 359
�50� Lactic�acidemia�and�defective�activity�of�pyruvate,�2-oxoglutarate,�and�branched�chain�oxoacid�dehydrogenases� 368
�51� Mitochondrial�encephalomyelopathy,�lactic�acidosis,�and�stroke-like�episodes�(MELAS)� 374
�52� Myoclonic�epilepsy�and�ragged�red�fiber�(MERRF)�disease� 382
�53� Neurodegeneration,�ataxia,�and�retinitis�pigmentosa�(NARP)� 388
�54� Kearns-Sayre�syndrome� 393
�55� Pearson�syndrome� 398
�56� The�mitochondrial�DNA�depletion�syndromes:�mitochondrial�DNA�polymerase�deficiency� 404
Part 6 disOrders Of carbOHydrate metabOlism
�57� Galactosemia� 415
�58� Glycogen�storage�diseases:�introduction� 425
�59� Glycogenosis�type�I�–�Von�Gierke�disease� 428
�60� Glycogenosis�type�II/Pompe/lysosomal�a-glucosidase�deficiency� 438
�61� Glycogenosis�type�III/amylo-1,6-glucosidase�(debrancher)�deficiency� 447
Part 7 PerOxisOmal disOrders
�62� Adrenoleukodystrophy� 459
�63� Neonatal�adrenoleukodystrophy/disorders�of�peroxisomal�biogenesis� 469
Part 8 disOrders Of Purine metabOlism
�64� Lesch-Nyhan�disease�and�variants� 483
�65� Adenine�phosphoribosyl-transferase�deficiency� 498
�66� Phosphoribosylpyrophosphate�synthetase�and�its�abnormalities� 503
�67� Adenosine�deaminase�deficiency� 507
�68� Adenylosuccinate�lyase�deficiency� 514
�69� Orotic�aciduria� 518
Contents vii
Part 9 disOrders Of transPOrt and mineral metabOlism
�70� Cystinuria� 525
�71� Cystinosis� 532
�72� Hartnup�disease� 540
�73� Histidinuria� 544
�74� Menkes�disease� 546
Part 10 mucOPOlysaccHaridOses
�75� Introduction�to�mucopolysaccharidoses� 555
�76� Hurler�disease/mucopolysaccharidosis�type�IHa-L-iduronidase�deficiency� 558
�77� Scheie�and�Hurler-Scheie�diseases/mucopolysaccharidosis�IS�and�IHS/a-iduronidase�deficiency� 566
�78� Hunter�disease/mucopolysaccharidosis�type�II/iduronate�sulfatase�deficiency� 572
�79� Sanfilippo�disease/mucopolysaccharidosis�type�III� 580
�80� Morquio�syndrome/mucopolysaccharidosis�type�IV/keratan�sulfaturia� 588
�81� Maroteaux-Lamy�disease/mucopolysaccharidosis�VI/N-acetylgalactosamine-4-sulfatase�deficiency� 597
�82� Sly�disease/b-glucuronidase�deficiency/mucopolysaccharidosis�VII� 605
Part 11 mucOliPidOses
�83� I-cell�disease/mucolipidosis�II� 613
�84� Mucolipidosis�III/pseudo-Hurler�polydystrophy/N-acetyl-glucosaminyl-l-phosphotransferase�deficiency� 621
Part 12 disOrders Of cHOlesterOl and neutral liPid metabOlism
�85� Familial�hypercholesterolemia� 631
�86� Mevalonic�aciduria� 642
�87� Lipoprotein�lipase�deficiency/type�I�hyperlipoproteinemia� 648
Part 13 liPid stOrage disOrders
�88� Fabry�disease� 659
�89� GM�gangliosidosis/b-galactosidase�deficiency� 666
1
�90� Tay-Sachs�disease/hexosaminidase�A�deficiency� 678
�91� Sandhoff�disease/GM�gangliosidosis/deficiency�of�hexosaminidase�A�and�B/hex-B�subunit�deficiency� 686
2
�92� GM�activator�deficiency/GM�gangliosidosis�–�deficiency�of�the�activator�protein� 694
2 2
�93� Gaucher�disease� 698
�94� Niemann-Pick�disease� 708
�95� Niemann-Pick�type�C�disease/cholesterol-processing�abnormality� 718
�96� Krabbe�disease/galactosylceramide�lipidosis/globoid�cell�leukodystrophy� 726
�97� Wolman�disease/cholesteryl�ester�storage�disease� 733
�98� Fucosidosis� 740
�99� a-Mannosidosis� 745
100� Galactosialidosis� 752
101� Metachromatic�leukodystrophy� 760
102� Multiple�sulfatase�deficiency� 769
Part 14 miscellaneOus
103� Congenital�disorder�of�glycosylation,�type�la� 781
104� Other�forms�of�congenital�disorders�of�glycosylation� 787
viii Contents
105� a-Antitrypsin�deficiency� 803
1
106� Canavan�disease/aspartoacylase�deficiency� 811
107� Ethylmalonic�encephalopathy� 819
108� Disorders�of�creatine�synthesis�or�transport� 827
Appendix� 833
Index�� 847
Contributor
Chapter 41
Zarazuela Zolkipli MD
Fellow in Biochemical Genetics and Mitochondrial Disease,
and Assistant Adjunct (Clinical) Professor, Neurosciences
University of California, San Diego, USA
Foreword
We must not cease from exploration, newborn population screening with subsequent early
And at the end of all our exploring, treatment is the most successful approach. Tandem mass
spectrometry has recently been implemented in newborn
Will be to arrive where we started,
screening programs in an increasing number of countries
And know the place for the first time. and other diagnostic high-throughput techniques
T.S. Elliot, Four Quartets, 1942. including primary molecular diagnostics are at the edge.
Handicap and suffering can be prevented from thousands
of children and their families. Although novel diagnostic
In 1942 only a handful of inborn errors of metabolism, and therapeutic possibilities never come for free, extended
sometimes called orphan diseases, were recognised with newborn screening is far more cost-effective than other
little to no treatment available. Destiny would take its medical advances. The costs of screening programs are
course and genetic counselling was virtually all that greatly outnumbered by the costs for direct health and
could be offered. Phenylketonuria was then shown by social costs in childhood.
Horst Bickel from the Children’s Hospital, Heidelberg, The field of inborn errors of metabolism or Metabolic
Germany, to be a treatable “genetic” disease in which Medicine is continuing to increase, both by its size and
early diagnosis and dietary treatment prevented impaired fortunately even more by our knowledge. Clinical expertise
mental development. Subsequently, many other inborn and a good cooperation between the referring physician
errors of metabolism became manageable in a similar and the metabolic specialist and a broad spectrum of
way, i.e. with substrate deprivation strategies: maple syrup metabolic investigations in the respective center are the
urine disease, galactosemia, fructosemia, tyrosinemia type key to successful diagnosis and treatment. Each disease and
2, and others. Pharmacological doses of vitamins proved each patient is different from each other. When molecular
useful in defects of cobalamin and biotin metabolism, genetics came to medicine, there was a widely held belief,
in distinct forms of homocystinuria, and some others. that knowing the genotype at the particular locus would
Avoiding of fasting was recognized as the cornerstone predict the corresponding phenotype and assist counseling
of successful therapy for defects of fatty acid oxidation, and treatment. It has become clear that this has been
ketogenesis and glycogenolysis. Initially progress had been rather naive. Although genotype-phenotype correlation
slow but has begun to explode over the last decennium is strong in some diseases, there is a huge number of
as current progress in understanding the molecular and examples where the phenotype cannot be explained by
pathophysiological bases of inborn errors of metabolism the mutations found. Even more, it has become obvious
funnels into the development of successful rational that, in addition to mutations of the affected gene and
therapies: new treatment protocols - new therapeutic environment, many other factors influence the phenotype.
agents (drugs and foods) - improved tissue transplantation, The role of numerous factors affecting post-transcriptional
enzyme replacement and gene therapy by other means. events, (including transport of RNA, protein synthesis,
The world health organisation (WHO) as well as the folding, and degradation.) and their mutual relationships
European Union (EU) have now announced genetic and are at best partly understood.
orphan diseases as a major health challenge of the future. The “‘Atlas of Inherited Metabolic Diseases” is now set
Among those the by now more than 500 inborn errors in its 3rd edition and has become the in-depth clinical
of metabolism are especially important because of their reference resource for inborn errors of metabolism,
relatively high frequency and because successful rationale combining in numerous details clinical presentation,
therapy is already available or will become so in the near treatment, monitoring and course. After brief but solid
future. As a group, they account for approx. 1 in 100 biochemical and molecular background information
births worldwide. Scientific and technological advances physicians will find the most comprehensive clinical
offer enormous benefit to patients suffering from inborn reference book for Metabolic Medicine with instructive
errors of metabolism often completely preventing life- descriptions of clinical situations and the possibility of
long burden and suffering. Early diagnosis by extended a visual double check on a metabolic syndrome with
xii Foreword
physical characteristics through the great photos found the care for their patients. Reflecting their experience
nowhere else. The content of this book draws from decades in the details and advice found in the “Atlas of Inherited
long clinical experiences in its best way, always asking what Metabolic Diseases” they may often find themselves
could have been done better. It has been and will continue remembering the beautiful lines of T.S. Elliot.
to be an invaluable source for metabolic physicians in
Georg F. Hoffmann, MD
Chairman of Pediatrics
University Children`s Hospital
Heidelberg, Germany
