Entry - #249270 - THIAMINE-RESPONSIVE MEGALOBLASTIC ANEMIA SYNDROME; TRMA - OMIM

 
ICD+
# 249270

THIAMINE-RESPONSIVE MEGALOBLASTIC ANEMIA SYNDROME; TRMA


Alternative titles; symbols

THIAMINE METABOLISM DYSFUNCTION SYNDROME 1 (MEGALOBLASTIC ANEMIA, DIABETES MELLITUS, AND DEAFNESS TYPE); THMD1
MEGALOBLASTIC ANEMIA, THIAMINE-RESPONSIVE, WITH DIABETES MELLITUS AND SENSORINEURAL DEAFNESS
ROGERS SYNDROME
THIAMINE-RESPONSIVE ANEMIA SYNDROME
THIAMINE-RESPONSIVE MYELODYSPLASIA


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
1q24.2 Thiamine-responsive megaloblastic anemia syndrome 249270 AR 3 SLC19A2 603941
Clinical Synopsis
 
Phenotypic Series
 

INHERITANCE
- Autosomal recessive
GROWTH
Height
- Short stature (in some patients)
HEAD & NECK
Ears
- Sensorineural deafness
Eyes
- Optic atrophy (in some patients)
- Maculopathy (uncommon)
- Cone-rod dystrophy (uncommon)
- Retinal degeneration (in some patients)
- Visual loss (in some patients)
- Nystagmus (in some patients)
CARDIOVASCULAR
Heart
- Congenital heart defects (in some patients)
- Atrial septal defect (uncommon)
- Ventricular septal defect (in some patients)
- Conduction defects (in some patients)
- Arrhythmias (in some patients)
- Cardiomyopathy (uncommon)
Vascular
- Cerebrovascular accidents (uncommon)
ABDOMEN
- Situs inversus (uncommon)
Gastrointestinal
- Gastroesophageal reflux (uncommon)
GENITOURINARY
Internal Genitalia (Male)
- Cryptorchidism (uncommon)
NEUROLOGIC
Central Nervous System
- Developmental delay (uncommon)
- Seizures (uncommon)
- Stroke (uncommon)
- Ataxia (uncommon)
ENDOCRINE FEATURES
- Diabetes mellitus
HEMATOLOGY
- Megaloblastic anemia
- Sideroblastic anemia
- Thrombocytopenia
LABORATORY ABNORMALITIES
- Serum thiamine is normal
MISCELLANEOUS
- Onset in early childhood (infancy to 6 years)
- Classic triad is megaloblastic anemia, diabetes, and deafness, but some patients may not have this triad
- Variable severity of phenotype and other features may be present
- Later onset associated with milder severity has been reported
- Anemia, diabetes, and deafness often show onset at different ages
- Diabetes and anemia respond to high doses of thiamine supplementation
MOLECULAR BASIS
- Caused by mutation in the solute carrier family 19 (thiamine transporter), member 2 gene (SLC19A2, 603941.0001)
▲ Close

TEXT

A number sign (#) is used with this entry because of evidence that thiamine-responsive megaloblastic anemia syndrome (TRMA), also known as thiamine metabolism dysfunction syndrome-1 (THMD1), is caused by homozygous mutation in the SLC19A2 (603941) gene, which encodes a thiamine transporter protein, on chromosome 1q24.

Description

Thiamine-responsive megaloblastic anemia syndrome (TRMA) comprises megaloblastic anemia, diabetes mellitus, and sensorineural deafness. Onset is typically between infancy and adolescence, but all of the cardinal findings are often not present initially. The anemia, and sometimes the diabetes, improves with high doses of thiamine. Other more variable features include optic atrophy, congenital heart defects, short stature, and stroke (summary by Bergmann et al., 2009).

Genetic Heterogeneity of Disorders Due to Thiamine Metabolism Dysfunction

See also episodic encephalopathies due to defects in thiamine metabolism: biotin-responsive basal ganglia disease (THMD2; 607483), caused by mutation in the SLC19A3 gene (606152) on chromosome 2q36; Amish-type microcephaly (THMD3; 607196) and bilateral striatal necrosis and progressive polyneuropathy (THMD4; 613710), both caused by mutation in the SLC25A19 gene (606521) on chromosome 17q25; and THMD5 (614458), caused by mutation in the TPK1 gene (606370) on chromosome 7q35.

Clinical Features

Rogers et al. (1969) described an 11-year-old girl with megaloblastic anemia responsive only to thiamine. She also had diabetes mellitus, amino aciduria, and sensorineural deafness. Viana and Carvalho (1978) described a 6-year-old girl with congenital megaloblastic anemia that responded completely only to pharmacologic doses of thiamine. Relapse occurred twice when thiamine was discontinued. As in the case of Rogers et al. (1969), the child also had latent diabetes mellitus and sensorineural deafness. Situs inversus viscerum totalis was also present. The parents were first cousins and were partially deaf. The syndrome was further delineated and autosomal recessive inheritance corroborated by Haworth et al. (1982), who described affected Pakistani brother and sister. The bone marrow showed megaloblastic erythropoiesis and many ringed sideroblasts, and, by electron microscopy, iron-laden mitochondria in erythroblasts. Autosomal recessive inheritance was demonstrated by the striking pedigree published by Mandel et al. (1984): 2 males and 3 females in 3 related sibships, each with closely related parents, were observed. The proband was the youngest reported case. She presented at age 3 months with severe anemia, diabetes, and deafness, all of which improved with high-dose thiamine treatment. The patient also showed generalized puffiness, hoarseness, and severe cardiac and neurologic disturbances, which also dramatically responded to administration of thiamine in large doses.

The abnormalities in the thiamine-responsive anemia syndrome are consistent with the picture of thiamine-deficient beriberi in childhood (Burgess, 1958). Hyperglycemia has been observed in beriberi, and diabetic glucose-tolerance curves that revert to normal with thiamine replacement are described in rats with experimental thiamine deficiency. The anemia can be megaloblastic, sideroblastic or aplastic.

Abboud et al. (1985) reported 3 brothers with diabetes mellitus, thiamine-responsive megaloblastic anemia, and sensorineural deafness. Two had also congenital septal defects of the heart. In 1 brother the activity of thiamine-dependent enzymes was measured, revealing low alpha-ketoglutarate dehydrogenase activity which might have been responsible for sideroblastic anemia with secondary megaloblastic changes. The anemia responded to thiamine but the diabetes did not.

Borgna-Pignatti et al. (1989) described 2 Italian children, related as first cousins, who developed megaloblastic and sideroblastic anemia, neutropenia, and borderline thrombocytopenia. These authors characterized these children as having DIDMOAD syndrome (222300). In both children, thiamine pyrophosphate in erythrocytes and thiamine pyrophosphokinase activity were lower than the lowest values observed in control subjects. A month after institution of treatment with thiamine, the hematologic findings had returned to normal and insulin requirements had decreased. Withdrawal of thiamine repeatedly induced relapse of the anemia and increase in insulin requirements. However, a later study by Neufeld et al. (1997) determined that the patients reported by Borgna-Pignatti et al. (1989) in fact had thiamine-responsive megaloblastic anemia syndrome, with linkage to chromosome 1q.

Bazarbachi et al. (1998) found reports of 15 patients with the triad of thiamine-responsive anemia, diabetes mellitus, and deafness associated with macrocytic anemia and sometimes moderate thrombocytopenia. Bone marrow aspirates usually showed ringed sideroblasts in addition to the megaloblastic changes. They described 2 new patients who presented with diabetes, deafness, and thiamine-responsive pancytopenia. Bone marrow aspirate and biopsy were typical of trilineage myelodysplasia. The findings suggested that thiamine may have a role in the regulation of hemopoiesis at the stem cell level. They proposed the designation 'thiamine-responsive myelodysplasia' for this disorder.

Villa et al. (2000) reported the case of a 20-year-old girl with TRMA associated with diabetes mellitus and bilateral sensorineural deafness. Megaloblastic anemia was diagnosed at 7 months and was successfully treated with multiple vitamin preparations. Diabetes was diagnosed at age 2 years and was treated with insulin for 6 months at a dose of 0.5 IU/kg BW. The diagnosis of TRMA was clinically confirmed when bilateral sensorineural deafness was detected. Thereafter, thiamine treatment was started (50 mg/day), and insulin was discontinued because of frequent episodes of hypoglycemia. At age 17 years, because of secondary amenorrhea and echographic findings of small ovarian cysts, the patient was diagnosed as having polycystic ovary syndrome and was treated with estro-progestins (12 cycles/yr of ciproterone, ethinyl estradiol). One year later, at age 18 years, the patient developed motor seizures initially involving the left leg, then rapidly extending to the whole body, followed by unconsciousness. Brain MRI and angiography showed severely reduced blood flow in the right middle cerebral artery, with a large ischemic area in the corresponding territory, absence of flow in the distal internal carotid arteries, and slight compensatory hypertrophy of the basilar artery. X-ray digital arteriography confirmed MRI findings and showed narrowing of the left superficial femoral and popliteal arteries.

Bergmann et al. (2009) reported 8 patients from 7 families with genetically confirmed TRMA. The patients were of various ethnic origin, including Korean, Indian, Lebanese, Honduran, Italian, Caucasian, and Portuguese. All had megaloblastic anemia, often with ringed sideroblasts, diabetes mellitus, which was often insulin-dependent, and deafness. Onset of anemia occurred between 11 months and 11 years of age; onset of diabetes between ages 1.5 years and 11 years; and onset of deafness between ages 8 months and 6 years in 6 patients and at age 30 in 1 patient. One patient had normal hearing at age 15 years. Treatment with high-dose thiamine resulted in improvement in the anemia and, in some cases, amelioration of the diabetes phenotype.


Clinical Management

The patient of Poggi et al. (1984) no longer needed insulin after the start of thiamine treatment. Poggi et al. (1989) and Rindi et al. (1992) reported further studies of the proband, a 5-year-old girl at the time of diagnosis, and her affected brother. Rindi et al. (1992) reported that with daily administration of a lipophilic form of thiamine with enhanced bioavailability, the girl was 'still well controlled as far as anaemia and deafness are concerned. During the last 3 years, her diabetes has required insulin therapy.' The boy was well controlled as far as anemia, deafness, and diabetes were concerned, but had developed progressive optic atrophy during the previous 2 years. Rindi et al. (1992) concluded that the cells from TRMA patients contain low levels of thiamine compounds, probably due to their inability to take up and retain physiologic concentrations of thiamine.


Mapping

Neufeld et al. (1997, 1997) performed homozygosity mapping and linkage mapping in 4 large kindreds of native Alaskan and Italian origin with TRMA. Strong evidence for linkage was found to a single marker on 1q23.2-q23.3; maximum lod = 3.7 for D1S1679. Sixteen markers spanning the region were examined in the Alaskan kindred, plus 2 additional consanguineous kindreds of Arab-Israeli origin. These results confirmed the putative disease gene interval, suggesting genetic homogeneity. Linkage analysis generated the highest combined lod score, 8.1 at theta = 0.0, with marker D1S2779. The Italian and Alaskan patients shared no haplotypes with each other nor with the Arab-Israeli families, suggesting that the disease arose independently on 3 different genetic backgrounds. Several heterozygous parents had diabetes mellitus, deafness, or megaloblastic anemia, raising the possibility that mutations at this locus predispose carriers to these manifestations.

Based on genetic recombination, homozygosity mapping, and linkage disequilibrium (highest lod score of 12.5 at D1S2799, at a recombination fraction of 0), Raz et al. (1998) further narrowed the TRMA interval to 4 cM. They analyzed an additional 7 families of diverse ethnic origin and confirmed homogeneity of the disease.

Banikazemi et al. (1999) narrowed the location of the TRMA locus to a 1.4-cM interval on 1q23.3. Using a P1-derived artificial chromosome (PAC) contig spanning the TRMA candidate region, Labay et al. (1999) clarified the order of genetic markers across the TRMA locus, provided 9 new polymorphic markers, and narrowed the locus to an approximately 400-kb region.


Inheritance

The transmission pattern of TRMA in the families reported by Labay et al. (1999) was consistent with autosomal recessive inheritance.


Molecular Genetics

By positional cloning, Labay et al. (1999) identified the SLC19A2 gene, which they called THTR1, within the critical TRMA locus region. In all affected members of 6 families segregating TRMA, they identified homozygous mutations in the SLC19A2 gene, which encodes a putative transmembrane protein homologous to the reduced folate carrier proteins. Labay et al. (1999) suggested that a defective thiamine transporter protein underlies the TRMA syndrome. They noted that studies by Rindi et al. (1994) and by Stagg et al. (1999) had suggested that deficiency in a high-affinity thiamine transporter may cause this disorder.

Scharfe et al. (2000) reported a girl with a trp358-to-ter mutation (603941.0009) in the SLC19A2 gene. In addition to TRMA, the girl had short stature, hepatosplenomegaly, retinal degeneration, and a brain MRI lesion. Biochemical analyses of muscle and skin biopsies revealed a severe deficiency of pyruvate dehydrogenase and complex I of the respiratory chain. These biochemical abnormalities responded to thiamine supplementation.


See Also:

REFERENCES

  1. Abboud, M. R., Alexander, D., Najjar, S. S. Diabetes mellitus, thiamine-dependent megaloblastic anemia, and sensorineural deafness associated with deficient alpha-ketoglutarate dehydrogenase activity. J. Pediat. 107: 537-541, 1985. [PubMed: 4045602, related citations] [Full Text]

  2. Banikazemi, M., Diaz, G. A., Voussough, P., Jalali, M., Desnick, R. J., Gelb, B. D. Localization of the thiamine-responsive megaloblastic anemia syndrome locus to a 1.4-cM region of 1q23. Molec. Genet. Metab. 66: 193-198, 1999. [PubMed: 10066388, related citations] [Full Text]

  3. Bazarbachi, A., Muakkit, S., Ayas, M., Taher, A., Salem, Z., Solh, H., Haidar, J. H. Thiamine-responsive myelodysplasia. Brit. J. Haemat. 102: 1098-1100, 1998. [PubMed: 9734663, related citations] [Full Text]

  4. Bergmann, A. K., Sahai, I., Falcone, J. F., Fleming, J., Bagg, A., Borgna-Pignati, C., Casey, R., Fabris, L, Hexner, E., Mathews, L., Ribeiro, M. L., Wierenga, K. J., Neufeld, E. J. Thiamine-responsive megaloblastic anemia: identification of novel compound heterozygotes and mutation update. J. Pediat. 155: 888-892, 2009. [PubMed: 19643445, related citations] [Full Text]

  5. Borgna-Pignatti, C., Marradi, P., Pinelli, L., Monetti, N., Patrini, C. Thiamine-responsive anemia in DIDMOAD syndrome. J. Pediat. 114: 405-410, 1989. [PubMed: 2537896, related citations] [Full Text]

  6. Burgess, R. C. Infantile beriberi. Fed. Proc. 17 (suppl. 2): 39-48, 1958.

  7. Duran, M., Wadman, S. K. Thiamine-responsive inborn errors of metabolism. J. Inherit. Metab. Dis. 8 (suppl. 1): 70-75, 1985. [PubMed: 3930844, related citations] [Full Text]

  8. Haworth, C., Evans, D. I. K., Mitra, J., Wickramasinghe, S. N. Thiamine responsive anaemia: a study of two further cases. Brit. J. Haemat. 50: 549-561, 1982. [PubMed: 6175336, related citations] [Full Text]

  9. Labay, V., Raz, T., Baron, D., Mandel, H., Williams, H., Barrett, T., Szargel, R., McDonald, L., Shalata, A., Nosaka, K., Gregory, S., Cohen, N. Mutations in SLC19A2 cause thiamine-responsive megaloblastic anaemia associated with diabetes mellitus and deafness. Nature Genet. 22: 300-304, 1999. [PubMed: 10391221, related citations] [Full Text]

  10. Mandel, H., Berant, M., Hazani, A., Naveh, Y. Thiamine-dependent beriberi in the 'thiamine-responsive anemia syndrome.'. New Eng. J. Med. 311: 836-838, 1984. [PubMed: 6472386, related citations] [Full Text]

  11. Neufeld, E. J., Mandel, H., Raz, T., Szargel, R., Yandava, C. N., Stagg, A., Faure, S., Barrett, T., Buist, N., Cohen, N. Localization of the gene for thiamine-responsive megaloblastic anemia syndrome, on the long arm of chromosome 1, by homozygosity mapping. Am. J. Hum. Genet. 61: 1335-1341, 1997. [PubMed: 9399900, related citations] [Full Text]

  12. Neufeld, E. J., Mandel, H., Raz, T., Yandava, C. N., Szargel, R., Stagg, A., Faure, S., Barrett, T. G., Cohen, N. Localization of the gene for the syndrome of thiamine-responsive megaloblastic anemia with diabetes and deafness to chromosome 1q23 by homozygosity mapping. (Abstract) Am. J. Hum. Genet. 61 (suppl.): A14 only, 1997.

  13. Poggi, V., Longo, G., DeVizia, B., Andria, G., Rindi, G., Patrini, C., Cassandro, E. Thiamin-responsive megaloblastic anaemia: a disorder of thiamin transport? J. Inherit. Metab. Dis. 7 (suppl. 2): 153-154, 1984. [PubMed: 6090807, related citations] [Full Text]

  14. Poggi, V., Rindi, G., Patrini, C., De Vizia, B., Longo, G., Andria, G. Studies on thiamine metabolism in thiamine-responsive megaloblastic anaemia. Europ. J. Pediat. 148: 307-311, 1989. [PubMed: 2540004, related citations] [Full Text]

  15. Raz, T., Barrett, T., Szargel, R., Mandel, H., Neufeld, E. J., Nosaka, K., Viana, M. B., Cohen, N. Refined mapping of the gene for thiamine-responsive megaloblastic anemia syndrome and evidence for genetic homogeneity. Hum. Genet. 103: 455-461, 1998. [PubMed: 9856490, related citations] [Full Text]

  16. Rindi, G., Casirola, D., Poggi, V., De Vizia, B., Patrini, C., Laforenza, U. Thiamine transport by erythrocytes and ghosts in thiamine-responsive megaloblastic anaemia. J. Inherit. Metab. Dis. 15: 231-242, 1992. [PubMed: 1326679, related citations] [Full Text]

  17. Rindi, G., Patrini, C., Laforenza, U., Mandel, H., Berant, M., Viana, M. B., Poggi, V., Zarra, A. N. Further studies on erythrocyte thiamin transport and phosphorylation in seven patients with thiamin-responsive megaloblastic anaemia. J. Inherit. Metab. Dis. 17: 667-677, 1994. [PubMed: 7707690, related citations] [Full Text]

  18. Rogers, L. E., Porter, F. S., Sidbury, J. B., Jr. Thiamine-responsive megaloblastic anemia. J. Pediat. 74: 494-504, 1969. [PubMed: 5767338, related citations] [Full Text]

  19. Scharfe, C., Hauschild, M., Klopstock, T., Janssen, A. J. M., Heidemann, P. H., Meitinger, T., Jaksch, M. A novel mutation in the thiamine responsive megaloblastic anaemia gene SLC19A2 in a patient with deficiency of respiratory chain complex I. J. Med. Genet. 37: 669-673, 2000. [PubMed: 10978358, related citations] [Full Text]

  20. Stagg, A. R., Fleming, J. C., Baker, M. A., Sakamoto, M., Cohen, N., Neufeld, E. J. Defective high-affinity thiamine transporter leads to cell death in thiamine-responsive megaloblastic anemia syndrome fibroblasts. J. Clin. Invest. 103: 723-729, 1999. [PubMed: 10074490, images, related citations] [Full Text]

  21. Viana, M. B., Carvalho, R. I. Thiamine-responsive megaloblastic anemia, sensorineural deafness, and diabetes mellitus: a new syndrome? J. Pediat. 93: 235-238, 1978. [PubMed: 671156, related citations] [Full Text]

  22. Villa, V., Rivellese, A., Di Salle, F., Iovine, C., Poggi, V., Capaldo, B. Acute ischemic stroke in a young woman with the thiamine-responsive megaloblastic anemia syndrome. J. Clin. Endocr. Metab. 85: 947-949, 2000. [PubMed: 10720020, related citations] [Full Text]


Contributors:
Cassandra L. Kniffin - updated : 2/8/2012
Michael J. Wright - updated : 8/9/2001
John A. Phillips, III - updated : 2/27/2001
Victor A. McKusick - updated : 6/24/1999
Ada Hamosh - updated : 3/10/1999
Victor A. McKusick - updated : 2/19/1999
Victor A. McKusick - updated : 2/16/1998
Victor A. McKusick - updated : 10/22/1997
Creation Date:
Victor A. McKusick : 6/4/1986
Edit History:
carol : 12/09/2022
carol : 08/03/2020
carol : 06/08/2017
carol : 12/30/2014
carol : 2/10/2012
ckniffin : 2/8/2012
terry : 4/20/2005
cwells : 8/16/2001
cwells : 8/14/2001
terry : 8/9/2001
alopez : 2/27/2001
alopez : 6/29/1999
terry : 6/24/1999
carol : 4/21/1999
alopez : 3/11/1999
alopez : 3/10/1999
carol : 2/22/1999
terry : 2/19/1999
mark : 2/25/1998
terry : 2/16/1998
terry : 10/28/1997
mark : 10/27/1997
terry : 10/22/1997
terry : 5/7/1994
mimadm : 2/19/1994
carol : 7/13/1992
carol : 7/8/1992
supermim : 3/17/1992
supermim : 3/20/1990

# 249270

THIAMINE-RESPONSIVE MEGALOBLASTIC ANEMIA SYNDROME; TRMA


Alternative titles; symbols

THIAMINE METABOLISM DYSFUNCTION SYNDROME 1 (MEGALOBLASTIC ANEMIA, DIABETES MELLITUS, AND DEAFNESS TYPE); THMD1
MEGALOBLASTIC ANEMIA, THIAMINE-RESPONSIVE, WITH DIABETES MELLITUS AND SENSORINEURAL DEAFNESS
ROGERS SYNDROME
THIAMINE-RESPONSIVE ANEMIA SYNDROME
THIAMINE-RESPONSIVE MYELODYSPLASIA


SNOMEDCT: 237617006;   ORPHA: 49827;   DO: 0090117;  


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
1q24.2 Thiamine-responsive megaloblastic anemia syndrome 249270 Autosomal recessive 3 SLC19A2 603941

TEXT

A number sign (#) is used with this entry because of evidence that thiamine-responsive megaloblastic anemia syndrome (TRMA), also known as thiamine metabolism dysfunction syndrome-1 (THMD1), is caused by homozygous mutation in the SLC19A2 (603941) gene, which encodes a thiamine transporter protein, on chromosome 1q24.

Description

Thiamine-responsive megaloblastic anemia syndrome (TRMA) comprises megaloblastic anemia, diabetes mellitus, and sensorineural deafness. Onset is typically between infancy and adolescence, but all of the cardinal findings are often not present initially. The anemia, and sometimes the diabetes, improves with high doses of thiamine. Other more variable features include optic atrophy, congenital heart defects, short stature, and stroke (summary by Bergmann et al., 2009).

Genetic Heterogeneity of Disorders Due to Thiamine Metabolism Dysfunction

See also episodic encephalopathies due to defects in thiamine metabolism: biotin-responsive basal ganglia disease (THMD2; 607483), caused by mutation in the SLC19A3 gene (606152) on chromosome 2q36; Amish-type microcephaly (THMD3; 607196) and bilateral striatal necrosis and progressive polyneuropathy (THMD4; 613710), both caused by mutation in the SLC25A19 gene (606521) on chromosome 17q25; and THMD5 (614458), caused by mutation in the TPK1 gene (606370) on chromosome 7q35.

Clinical Features

Rogers et al. (1969) described an 11-year-old girl with megaloblastic anemia responsive only to thiamine. She also had diabetes mellitus, amino aciduria, and sensorineural deafness. Viana and Carvalho (1978) described a 6-year-old girl with congenital megaloblastic anemia that responded completely only to pharmacologic doses of thiamine. Relapse occurred twice when thiamine was discontinued. As in the case of Rogers et al. (1969), the child also had latent diabetes mellitus and sensorineural deafness. Situs inversus viscerum totalis was also present. The parents were first cousins and were partially deaf. The syndrome was further delineated and autosomal recessive inheritance corroborated by Haworth et al. (1982), who described affected Pakistani brother and sister. The bone marrow showed megaloblastic erythropoiesis and many ringed sideroblasts, and, by electron microscopy, iron-laden mitochondria in erythroblasts. Autosomal recessive inheritance was demonstrated by the striking pedigree published by Mandel et al. (1984): 2 males and 3 females in 3 related sibships, each with closely related parents, were observed. The proband was the youngest reported case. She presented at age 3 months with severe anemia, diabetes, and deafness, all of which improved with high-dose thiamine treatment. The patient also showed generalized puffiness, hoarseness, and severe cardiac and neurologic disturbances, which also dramatically responded to administration of thiamine in large doses.

The abnormalities in the thiamine-responsive anemia syndrome are consistent with the picture of thiamine-deficient beriberi in childhood (Burgess, 1958). Hyperglycemia has been observed in beriberi, and diabetic glucose-tolerance curves that revert to normal with thiamine replacement are described in rats with experimental thiamine deficiency. The anemia can be megaloblastic, sideroblastic or aplastic.

Abboud et al. (1985) reported 3 brothers with diabetes mellitus, thiamine-responsive megaloblastic anemia, and sensorineural deafness. Two had also congenital septal defects of the heart. In 1 brother the activity of thiamine-dependent enzymes was measured, revealing low alpha-ketoglutarate dehydrogenase activity which might have been responsible for sideroblastic anemia with secondary megaloblastic changes. The anemia responded to thiamine but the diabetes did not.

Borgna-Pignatti et al. (1989) described 2 Italian children, related as first cousins, who developed megaloblastic and sideroblastic anemia, neutropenia, and borderline thrombocytopenia. These authors characterized these children as having DIDMOAD syndrome (222300). In both children, thiamine pyrophosphate in erythrocytes and thiamine pyrophosphokinase activity were lower than the lowest values observed in control subjects. A month after institution of treatment with thiamine, the hematologic findings had returned to normal and insulin requirements had decreased. Withdrawal of thiamine repeatedly induced relapse of the anemia and increase in insulin requirements. However, a later study by Neufeld et al. (1997) determined that the patients reported by Borgna-Pignatti et al. (1989) in fact had thiamine-responsive megaloblastic anemia syndrome, with linkage to chromosome 1q.

Bazarbachi et al. (1998) found reports of 15 patients with the triad of thiamine-responsive anemia, diabetes mellitus, and deafness associated with macrocytic anemia and sometimes moderate thrombocytopenia. Bone marrow aspirates usually showed ringed sideroblasts in addition to the megaloblastic changes. They described 2 new patients who presented with diabetes, deafness, and thiamine-responsive pancytopenia. Bone marrow aspirate and biopsy were typical of trilineage myelodysplasia. The findings suggested that thiamine may have a role in the regulation of hemopoiesis at the stem cell level. They proposed the designation 'thiamine-responsive myelodysplasia' for this disorder.

Villa et al. (2000) reported the case of a 20-year-old girl with TRMA associated with diabetes mellitus and bilateral sensorineural deafness. Megaloblastic anemia was diagnosed at 7 months and was successfully treated with multiple vitamin preparations. Diabetes was diagnosed at age 2 years and was treated with insulin for 6 months at a dose of 0.5 IU/kg BW. The diagnosis of TRMA was clinically confirmed when bilateral sensorineural deafness was detected. Thereafter, thiamine treatment was started (50 mg/day), and insulin was discontinued because of frequent episodes of hypoglycemia. At age 17 years, because of secondary amenorrhea and echographic findings of small ovarian cysts, the patient was diagnosed as having polycystic ovary syndrome and was treated with estro-progestins (12 cycles/yr of ciproterone, ethinyl estradiol). One year later, at age 18 years, the patient developed motor seizures initially involving the left leg, then rapidly extending to the whole body, followed by unconsciousness. Brain MRI and angiography showed severely reduced blood flow in the right middle cerebral artery, with a large ischemic area in the corresponding territory, absence of flow in the distal internal carotid arteries, and slight compensatory hypertrophy of the basilar artery. X-ray digital arteriography confirmed MRI findings and showed narrowing of the left superficial femoral and popliteal arteries.

Bergmann et al. (2009) reported 8 patients from 7 families with genetically confirmed TRMA. The patients were of various ethnic origin, including Korean, Indian, Lebanese, Honduran, Italian, Caucasian, and Portuguese. All had megaloblastic anemia, often with ringed sideroblasts, diabetes mellitus, which was often insulin-dependent, and deafness. Onset of anemia occurred between 11 months and 11 years of age; onset of diabetes between ages 1.5 years and 11 years; and onset of deafness between ages 8 months and 6 years in 6 patients and at age 30 in 1 patient. One patient had normal hearing at age 15 years. Treatment with high-dose thiamine resulted in improvement in the anemia and, in some cases, amelioration of the diabetes phenotype.


Clinical Management

The patient of Poggi et al. (1984) no longer needed insulin after the start of thiamine treatment. Poggi et al. (1989) and Rindi et al. (1992) reported further studies of the proband, a 5-year-old girl at the time of diagnosis, and her affected brother. Rindi et al. (1992) reported that with daily administration of a lipophilic form of thiamine with enhanced bioavailability, the girl was 'still well controlled as far as anaemia and deafness are concerned. During the last 3 years, her diabetes has required insulin therapy.' The boy was well controlled as far as anemia, deafness, and diabetes were concerned, but had developed progressive optic atrophy during the previous 2 years. Rindi et al. (1992) concluded that the cells from TRMA patients contain low levels of thiamine compounds, probably due to their inability to take up and retain physiologic concentrations of thiamine.


Mapping

Neufeld et al. (1997, 1997) performed homozygosity mapping and linkage mapping in 4 large kindreds of native Alaskan and Italian origin with TRMA. Strong evidence for linkage was found to a single marker on 1q23.2-q23.3; maximum lod = 3.7 for D1S1679. Sixteen markers spanning the region were examined in the Alaskan kindred, plus 2 additional consanguineous kindreds of Arab-Israeli origin. These results confirmed the putative disease gene interval, suggesting genetic homogeneity. Linkage analysis generated the highest combined lod score, 8.1 at theta = 0.0, with marker D1S2779. The Italian and Alaskan patients shared no haplotypes with each other nor with the Arab-Israeli families, suggesting that the disease arose independently on 3 different genetic backgrounds. Several heterozygous parents had diabetes mellitus, deafness, or megaloblastic anemia, raising the possibility that mutations at this locus predispose carriers to these manifestations.

Based on genetic recombination, homozygosity mapping, and linkage disequilibrium (highest lod score of 12.5 at D1S2799, at a recombination fraction of 0), Raz et al. (1998) further narrowed the TRMA interval to 4 cM. They analyzed an additional 7 families of diverse ethnic origin and confirmed homogeneity of the disease.

Banikazemi et al. (1999) narrowed the location of the TRMA locus to a 1.4-cM interval on 1q23.3. Using a P1-derived artificial chromosome (PAC) contig spanning the TRMA candidate region, Labay et al. (1999) clarified the order of genetic markers across the TRMA locus, provided 9 new polymorphic markers, and narrowed the locus to an approximately 400-kb region.


Inheritance

The transmission pattern of TRMA in the families reported by Labay et al. (1999) was consistent with autosomal recessive inheritance.


Molecular Genetics

By positional cloning, Labay et al. (1999) identified the SLC19A2 gene, which they called THTR1, within the critical TRMA locus region. In all affected members of 6 families segregating TRMA, they identified homozygous mutations in the SLC19A2 gene, which encodes a putative transmembrane protein homologous to the reduced folate carrier proteins. Labay et al. (1999) suggested that a defective thiamine transporter protein underlies the TRMA syndrome. They noted that studies by Rindi et al. (1994) and by Stagg et al. (1999) had suggested that deficiency in a high-affinity thiamine transporter may cause this disorder.

Scharfe et al. (2000) reported a girl with a trp358-to-ter mutation (603941.0009) in the SLC19A2 gene. In addition to TRMA, the girl had short stature, hepatosplenomegaly, retinal degeneration, and a brain MRI lesion. Biochemical analyses of muscle and skin biopsies revealed a severe deficiency of pyruvate dehydrogenase and complex I of the respiratory chain. These biochemical abnormalities responded to thiamine supplementation.


See Also:

Duran and Wadman (1985)

REFERENCES

  1. Abboud, M. R., Alexander, D., Najjar, S. S. Diabetes mellitus, thiamine-dependent megaloblastic anemia, and sensorineural deafness associated with deficient alpha-ketoglutarate dehydrogenase activity. J. Pediat. 107: 537-541, 1985. [PubMed: 4045602] [Full Text: https://doi.org/10.1016/s0022-3476(85)80011-1]

  2. Banikazemi, M., Diaz, G. A., Voussough, P., Jalali, M., Desnick, R. J., Gelb, B. D. Localization of the thiamine-responsive megaloblastic anemia syndrome locus to a 1.4-cM region of 1q23. Molec. Genet. Metab. 66: 193-198, 1999. [PubMed: 10066388] [Full Text: https://doi.org/10.1006/mgme.1998.2799]

  3. Bazarbachi, A., Muakkit, S., Ayas, M., Taher, A., Salem, Z., Solh, H., Haidar, J. H. Thiamine-responsive myelodysplasia. Brit. J. Haemat. 102: 1098-1100, 1998. [PubMed: 9734663] [Full Text: https://doi.org/10.1046/j.1365-2141.1998.00861.x]

  4. Bergmann, A. K., Sahai, I., Falcone, J. F., Fleming, J., Bagg, A., Borgna-Pignati, C., Casey, R., Fabris, L, Hexner, E., Mathews, L., Ribeiro, M. L., Wierenga, K. J., Neufeld, E. J. Thiamine-responsive megaloblastic anemia: identification of novel compound heterozygotes and mutation update. J. Pediat. 155: 888-892, 2009. [PubMed: 19643445] [Full Text: https://doi.org/10.1016/j.jpeds.2009.06.017]

  5. Borgna-Pignatti, C., Marradi, P., Pinelli, L., Monetti, N., Patrini, C. Thiamine-responsive anemia in DIDMOAD syndrome. J. Pediat. 114: 405-410, 1989. [PubMed: 2537896] [Full Text: https://doi.org/10.1016/s0022-3476(89)80558-x]

  6. Burgess, R. C. Infantile beriberi. Fed. Proc. 17 (suppl. 2): 39-48, 1958.

  7. Duran, M., Wadman, S. K. Thiamine-responsive inborn errors of metabolism. J. Inherit. Metab. Dis. 8 (suppl. 1): 70-75, 1985. [PubMed: 3930844] [Full Text: https://doi.org/10.1007/BF01800663]

  8. Haworth, C., Evans, D. I. K., Mitra, J., Wickramasinghe, S. N. Thiamine responsive anaemia: a study of two further cases. Brit. J. Haemat. 50: 549-561, 1982. [PubMed: 6175336] [Full Text: https://doi.org/10.1111/j.1365-2141.1982.tb01955.x]

  9. Labay, V., Raz, T., Baron, D., Mandel, H., Williams, H., Barrett, T., Szargel, R., McDonald, L., Shalata, A., Nosaka, K., Gregory, S., Cohen, N. Mutations in SLC19A2 cause thiamine-responsive megaloblastic anaemia associated with diabetes mellitus and deafness. Nature Genet. 22: 300-304, 1999. [PubMed: 10391221] [Full Text: https://doi.org/10.1038/10372]

  10. Mandel, H., Berant, M., Hazani, A., Naveh, Y. Thiamine-dependent beriberi in the 'thiamine-responsive anemia syndrome.'. New Eng. J. Med. 311: 836-838, 1984. [PubMed: 6472386] [Full Text: https://doi.org/10.1056/NEJM198409273111307]

  11. Neufeld, E. J., Mandel, H., Raz, T., Szargel, R., Yandava, C. N., Stagg, A., Faure, S., Barrett, T., Buist, N., Cohen, N. Localization of the gene for thiamine-responsive megaloblastic anemia syndrome, on the long arm of chromosome 1, by homozygosity mapping. Am. J. Hum. Genet. 61: 1335-1341, 1997. [PubMed: 9399900] [Full Text: https://doi.org/10.1086/301642]

  12. Neufeld, E. J., Mandel, H., Raz, T., Yandava, C. N., Szargel, R., Stagg, A., Faure, S., Barrett, T. G., Cohen, N. Localization of the gene for the syndrome of thiamine-responsive megaloblastic anemia with diabetes and deafness to chromosome 1q23 by homozygosity mapping. (Abstract) Am. J. Hum. Genet. 61 (suppl.): A14 only, 1997.

  13. Poggi, V., Longo, G., DeVizia, B., Andria, G., Rindi, G., Patrini, C., Cassandro, E. Thiamin-responsive megaloblastic anaemia: a disorder of thiamin transport? J. Inherit. Metab. Dis. 7 (suppl. 2): 153-154, 1984. [PubMed: 6090807] [Full Text: https://doi.org/10.1007/978-94-009-5612-4_51]

  14. Poggi, V., Rindi, G., Patrini, C., De Vizia, B., Longo, G., Andria, G. Studies on thiamine metabolism in thiamine-responsive megaloblastic anaemia. Europ. J. Pediat. 148: 307-311, 1989. [PubMed: 2540004] [Full Text: https://doi.org/10.1007/BF00444120]

  15. Raz, T., Barrett, T., Szargel, R., Mandel, H., Neufeld, E. J., Nosaka, K., Viana, M. B., Cohen, N. Refined mapping of the gene for thiamine-responsive megaloblastic anemia syndrome and evidence for genetic homogeneity. Hum. Genet. 103: 455-461, 1998. [PubMed: 9856490] [Full Text: https://doi.org/10.1007/s004390050850]

  16. Rindi, G., Casirola, D., Poggi, V., De Vizia, B., Patrini, C., Laforenza, U. Thiamine transport by erythrocytes and ghosts in thiamine-responsive megaloblastic anaemia. J. Inherit. Metab. Dis. 15: 231-242, 1992. [PubMed: 1326679] [Full Text: https://doi.org/10.1007/BF01799637]

  17. Rindi, G., Patrini, C., Laforenza, U., Mandel, H., Berant, M., Viana, M. B., Poggi, V., Zarra, A. N. Further studies on erythrocyte thiamin transport and phosphorylation in seven patients with thiamin-responsive megaloblastic anaemia. J. Inherit. Metab. Dis. 17: 667-677, 1994. [PubMed: 7707690] [Full Text: https://doi.org/10.1007/BF00712009]

  18. Rogers, L. E., Porter, F. S., Sidbury, J. B., Jr. Thiamine-responsive megaloblastic anemia. J. Pediat. 74: 494-504, 1969. [PubMed: 5767338] [Full Text: https://doi.org/10.1016/s0022-3476(69)80031-4]

  19. Scharfe, C., Hauschild, M., Klopstock, T., Janssen, A. J. M., Heidemann, P. H., Meitinger, T., Jaksch, M. A novel mutation in the thiamine responsive megaloblastic anaemia gene SLC19A2 in a patient with deficiency of respiratory chain complex I. J. Med. Genet. 37: 669-673, 2000. [PubMed: 10978358] [Full Text: https://doi.org/10.1136/jmg.37.9.669]

  20. Stagg, A. R., Fleming, J. C., Baker, M. A., Sakamoto, M., Cohen, N., Neufeld, E. J. Defective high-affinity thiamine transporter leads to cell death in thiamine-responsive megaloblastic anemia syndrome fibroblasts. J. Clin. Invest. 103: 723-729, 1999. [PubMed: 10074490] [Full Text: https://doi.org/10.1172/JCI3895]

  21. Viana, M. B., Carvalho, R. I. Thiamine-responsive megaloblastic anemia, sensorineural deafness, and diabetes mellitus: a new syndrome? J. Pediat. 93: 235-238, 1978. [PubMed: 671156] [Full Text: https://doi.org/10.1016/s0022-3476(78)80503-4]

  22. Villa, V., Rivellese, A., Di Salle, F., Iovine, C., Poggi, V., Capaldo, B. Acute ischemic stroke in a young woman with the thiamine-responsive megaloblastic anemia syndrome. J. Clin. Endocr. Metab. 85: 947-949, 2000. [PubMed: 10720020] [Full Text: https://doi.org/10.1210/jcem.85.3.6419]


Contributors:
Cassandra L. Kniffin - updated : 2/8/2012
Michael J. Wright - updated : 8/9/2001
John A. Phillips, III - updated : 2/27/2001
Victor A. McKusick - updated : 6/24/1999
Ada Hamosh - updated : 3/10/1999
Victor A. McKusick - updated : 2/19/1999
Victor A. McKusick - updated : 2/16/1998
Victor A. McKusick - updated : 10/22/1997

Creation Date:
Victor A. McKusick : 6/4/1986

Edit History:
carol : 12/09/2022
carol : 08/03/2020
carol : 06/08/2017
carol : 12/30/2014
carol : 2/10/2012
ckniffin : 2/8/2012
terry : 4/20/2005
cwells : 8/16/2001
cwells : 8/14/2001
terry : 8/9/2001
alopez : 2/27/2001
alopez : 6/29/1999
terry : 6/24/1999
carol : 4/21/1999
alopez : 3/11/1999
alopez : 3/10/1999
carol : 2/22/1999
terry : 2/19/1999
mark : 2/25/1998
terry : 2/16/1998
terry : 10/28/1997
mark : 10/27/1997
terry : 10/22/1997
terry : 5/7/1994
mimadm : 2/19/1994
carol : 7/13/1992
carol : 7/8/1992
supermim : 3/17/1992
supermim : 3/20/1990



NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.

NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.
Printed: March 5, 2025