Rothmund-Thomson Syndrome

Back

Background

Rothmund-Thomson syndrome, or poikiloderma congenitale, is a rare autosomal recessive disorder attributed to mutations of the RECQL4 helicase gene on 8q24.[1, 2, 3] Key features include early photosensitivity and poikilodermatous skin changes, juvenile cataracts, skeletal dysplasias, and a predisposition to osteosarcoma and skin cancer.[4, 5]

Etiology

Rothmund-Thomson syndrome (poikiloderma congenitale) has been attributed to mutations of the RECQL4 gene on 8q24, which encodes a RecQ DNA helicase.[1, 2, 3, 6, 7] RecQ helicases are enzymes that function in DNA replication and repair and appear to be essential for the maintenance of genomic stability.[8, 9, 10, 11, 12, 13, 14, 15, 16] A strong correlation appears to exist between the presence of truncating, loss-of-function mutations of the RECQL4 gene, and the development of skeletal abnormalities and osteosarcoma.

Epidemiology

Frequency

Approximately 300 cases of Rothmund-Thomson syndrome (poikiloderma congenitale) have been reported in the scientific literature worldwide.

Sex

Whether Rothmund-Thomson syndrome (poikiloderma congenitale) has a predilection for one sex over the other is unclear. An equal female-to-male ratio, a female predominance (1.4:1), and a male predominance (2:1) have all been reported in various case series.

Age

More than 90% of patients with Rothmund-Thomson syndrome (poikiloderma congenitale) develop the initial skin manifestations during the first year of life, usually from age 3-6 months. Rarely, the skin changes may be present at birth, or they may appear as late as age 2 years.

Prognosis

In the absence of malignancy, patients usually have a normal life span.

Patient Education

Patients and their families should be educated regarding the potential signs and symptoms of osteosarcoma such as bone pain, swelling, or an enlarging lesion on a limb.

The use of broad-spectrum photoprotection should be emphasized. Monitoring for nonhealing, ulcerated, or enlarging skin lesions suggestive of malignancy should also be encouraged.

History

Patients with Rothmund-Thomson syndrome (poikiloderma congenitale) generally present with a rash (poikiloderma), small stature, and skeletal dysplasias.

The characteristic skin findings are the most consistent feature of the syndrome. The acute phase begins in early infancy as red patches or edematous plaques, sometimes with blistering. The cheeks are usually first involved, with later spread to other areas of the face, the extremities, and the buttocks. Over months to years, the rash enters a chronic stage characterized by poikiloderma (atrophy, telangiectasias, and pigmentary changes).

Photosensitivity is a feature in more than 30% of cases.

Gastrointestinal problems such as chronic emesis or diarrhea may occur in infancy and early childhood but usually resolve spontaneously. Celiac disease has been reported.[17]

Hematological abnormalities ranging from isolated anemia and neutropenia to myelodysplasia and leukemia have also been noted to occur.

Physical Examination

In Rothmund-Thomson syndrome (poikiloderma congenitale), irregular erythema and edema of the skin is replaced by reticulated red-brown patches associated with punctate atrophy and telangiectasias (poikiloderma). These characteristic skin changes are typically seen on the face, extensor extremities, and buttocks with sparing of the chest, abdomen, and back. See the images below.



View Image

Note the poikiloderma and skeletal abnormalities.



View Image

Close-up of poikiloderma.



View Image

Close-up of poikiloderma.

Acral hyperkeratotic lesions on the elbows, knees, hands, and feet can be seen at puberty. Palmar keratoderma has been reported.[17]

Patients may have sparse scalp hair, eyelashes, and eyebrows. Premature canities may also be observed.

Nail abnormalities such as dystrophic or atrophic nails may be seen.

Dental abnormalities include malformation, microdontia, and failure of eruption.

Juvenile cataracts have been reported to occur with a prevalence that has been estimated at less than 10% in some series and as high as 40-50% in others. Most develop between age 3 and 7 years.

Patients usually have short stature, which ranges from dwarfism to a small build. More than half of patients have skeletal abnormalities, most frequently a characteristic facies (with frontal bossing, saddle nose, and micrognathia), disproportionately small hands and feet, absent or malformed radii, and absent or partially formed thumbs.

Sexual abnormalities, affecting about 25% of adult patients, include hypoplasia and/or aplasia of the external genitalia, amenorrhea, lack of secondary sex characteristics, and infertility.

Otsu et al report a patient who had some uncommon complications of Rothmund-Thomson syndrome (poikiloderma congenitale) and many typical features, but the patient did not have a mutation in RECQL4; therefore, they suggest this case was a "peculiar" variant of Rothmund-Thomson syndrome.[18]

Complications

Osteosarcomas have been reported to arise in as many as 32% of patients with Rothmund-Thomson syndrome (poikiloderma congenitale). They most frequently arise in the tibia/fibula. The development of osteosarcoma among patients with the syndrome has been strongly correlated with truncating mutations of RECQL4.[19]

The development of nonmelanoma skin cancers, with an earlier onset than that of the general population, has also been reported. The majority of cases were either Bowen disease or squamous cell carcinoma.[20] Squamous cell carcinoma may develop in acral keratoses.

While most skin cancers reported in patients with Rothmund-Thomson syndrome (poikiloderma congenitale) have been nonmelanoma skin cancers; Howell and Bray reported the occurrence of an amelanotic melanoma in a young woman with Rothmund-Thomson syndrome (poikiloderma congenitale).[21]

Genetic Testing

By sequence analysis of RECQL4, a disease-causing mutation can be identified in approximately 66% of individuals diagnosed with Rothmund-Thomson syndrome.[5, 23] Although the sensitivity of the genetic test is 66%, the clinical specificity approaches 100%; thus a negative test does not rule out the diagnosis of Rothmund-Thomson syndrome but a positive test is confirmatory.

A Clinical Utility Gene Card for Rothmund-Thomson syndrome, published in 2012, summarizes guidelines for the use of genetic testing for the syndrome using mutational analysis of the RECQL4 gene.[24] In classic cases, a correct diagnosis may be made on clinical findings (such as early-onset facial poikiloderma accompanied by radial-ray defects, growth defects, and sparse hair). Genetic testing of the RECQL4 gene is of particular value in evaluating borderline or atypical cases in which other genodermatoses presenting with poikiloderma or other overlapping features such as poikiloderma with neutropenia, dyskeratosis congenita, Werner syndrome, and Fanconi anemia must also be considered. Additionally, the test should be offered to all juvenile osteosarcoma cases with poikilodermalike lesions. In these cases, genetic testing of the RECQL4 gene would allow for establishment of the correct diagnosis and thus accurate syndrome-specific surveillance.

Imaging Studies

In Rothmund-Thomson syndrome (poikiloderma congenitale), baseline skeletal radiographs of the long bones by age 5 years are recommended due to the high frequency of skeletal dysplasias, many of which may be clinically asymptomatic.[25]

Histologic Findings

Histologic examination of poikilodermatous skin in children reveals a flattened, atrophic epidermis with derma-epidermal junction edema and dermal vasodilatation, possibly with a perivascular lymphocytic infiltrate. Adult skin in exposed areas reveals patchy Bowenoid dyskeratosis in the epidermis and fragmented dermal elastic tissue.

Medical Care

Persons with Rothmund-Thomson syndrome (poikiloderma congenitale) should apply sunscreens with UVA and UVB coverage regularly. Additionally, keratolytics and retinoids have been somewhat successful in treating the hyperkeratotic lesions.

Surgical Care

Telangiectases can be treated with pulsed-dye laser therapy.[26]

Consultations

Consultation with an ophthalmologist is recommended for annual eye examinations to screen for the development of juvenile cataracts.

Referrals to a dentist, an orthopedist, an endocrinologist, and a hematologist/oncologist may be indicated based on the related signs and symptoms.

A dermatologist may be consulted to monitor for the development of skin cancers.

Medication Summary

The goals of pharmacotherapy for Rothmund-Thomson syndrome (poikiloderma congenitale) are to reduce morbidity and to prevent complications.

Isotretinoin (Amnesteem, Claravis, Myorisan, Sotrel)

Clinical Context:  Isotretinoin is a synthetic 13-cis isomer of the naturally occurring tretinoin (trans-retinoic acid). It is approved for use in severe recalcitrant nodular acne.

A US Food and Drug Administration–mandated registry is now in place for all individuals prescribing, dispensing, or taking isotretinoin. For more information on this registry, see iPLEDGE. This registry aims to further decrease the risk of pregnancy and other unwanted and potentially dangerous adverse effects during a course of isotretinoin therapy.

Tretinoin topical (Atralin, Refissa, Renova, Avita, Retin-A)

Clinical Context:  Tretinoin inhibits microcomedo formation and eliminates lesions. It makes keratinocytes in sebaceous follicles less adherent and easier to remove. Tretinoin topical is available as 0.025%, 0.05%, and 0.1% creams and 0.01% and 0.025% gels.

Acitretin (Soriatane)

Clinical Context:  Acitretin is a metabolite of etretinate and related to both retinoic acid and retinol (vitamin A). Its mechanism of action is unknown. However, it is thought to exert therapeutic effect by modulating keratinocyte differentiation, keratinocyte hyperproliferation, and tissue infiltration by inflammatory cells. Acitretin is approved for the treatment of severe psoriasis.

Class Summary

These agents decrease the cohesiveness of abnormal hyperproliferative keratinocytes, and they may reduce the potential for malignant degeneration. They also modulate keratinocyte differentiation.

Salicylic acid topical (Clean & Clear Advantage, Neutrogena)

Clinical Context:  By dissolving the intercellular cement substance, salicylic acid produces desquamation of the horny layer of skin, while not affecting the structure of viable epidermis.

Class Summary

This agent causes cornified epithelium to swell, soften, macerate, and then desquamate.

Author

Sylvia Hsu, MD, Professor, Department of Dermatology, Baylor College of Medicine

Disclosure: Nothing to disclose.

Coauthor(s)

Saira J George, MD, Assistant Professor, Department of Dermatology, Division of Internal Medicine, The University of Texas MD Anderson Cancer Center

Disclosure: Nothing to disclose.

Specialty Editors

Michael J Wells, MD, FAAD, Dermatologic/Mohs Surgeon, The Surgery Center at Plano Dermatology

Disclosure: Nothing to disclose.

Van Perry, MD, Assistant Professor, Department of Medicine, Division of Dermatology, University of Texas School of Medicine at San Antonio

Disclosure: Nothing to disclose.

Chief Editor

Dirk M Elston, MD, Professor and Chairman, Department of Dermatology and Dermatologic Surgery, Medical University of South Carolina College of Medicine

Disclosure: Nothing to disclose.

Additional Contributors

Andrea Leigh Zaenglein, MD, Professor of Dermatology and Pediatrics, Department of Dermatology, Hershey Medical Center, Pennsylvania State University College of Medicine

Disclosure: Received consulting fee from Galderma for consulting; Received consulting fee from Valeant for consulting; Received consulting fee from Promius for consulting; Received consulting fee from Anacor for consulting; Received grant/research funds from Stiefel for investigator; Received grant/research funds from Astellas for investigator; Received grant/research funds from Ranbaxy for other; Received consulting fee from Ranbaxy for consulting.

References

  1. Kitao S, Shimamoto A, Goto M, et al. Mutations in RECQL4 cause a subset of cases of Rothmund-Thomson syndrome. Nat Genet. 1999 May. 22(1):82-4. [View Abstract]
  2. Kitao S, Lindor NM, Shiratori M, Furuichi Y, Shimamoto A. Rothmund-thomson syndrome responsible gene, RECQL4: genomic structure and products. Genomics. 1999 Nov 1. 61(3):268-76. [View Abstract]
  3. Larizza L, Magnani I, Roversi G. Rothmund-Thomson syndrome and RECQL4 defect: splitting and lumping. Cancer Lett. 2006 Jan 28. 232(1):107-20. [View Abstract]
  4. Leonard A, Craft AW, Moss C, Malcolm AJ. Osteogenic sarcoma in the Rothmund-Thomson syndrome. Med Pediatr Oncol. 1996 Apr. 26(4):249-53. [View Abstract]
  5. Wang LL, Gannavarapu A, Kozinetz CA, et al. Association between osteosarcoma and deleterious mutations in the RECQL4 gene in Rothmund-Thomson syndrome. J Natl Cancer Inst. 2003 May 7. 95(9):669-74. [View Abstract]
  6. Macris MA, Krejci L, Bussen W, Shimamoto A, Sung P. Biochemical characterization of the RECQ4 protein, mutated in Rothmund-Thomson syndrome. DNA Repair (Amst). 2006 Feb 3. 5(2):172-80. [View Abstract]
  7. Suter AA, Itin P, Heinimann K, Ahmed M, Ashraf T, Fryssira H, et al. Rothmund-Thomson Syndrome: novel pathogenic mutations and frequencies of variants in the RECQL4 and USB1 (C16orf57) gene. Mol Genet Genomic Med. 2016 May. 4 (3):359-66. [View Abstract]
  8. Werner SR, Prahalad AK, Yang J, Hock JM. RECQL4-deficient cells are hypersensitive to oxidative stress/damage: Insights for osteosarcoma prevalence and heterogeneity in Rothmund-Thomson syndrome. Biochem Biophys Res Commun. 2006 Jun 23. 345(1):403-9. [View Abstract]
  9. Woo LL, Futami K, Shimamoto A, Furuichi Y, Frank KM. The Rothmund-Thomson gene product RECQL4 localizes to the nucleolus in response to oxidative stress. Exp Cell Res. 2006 Oct 15. 312(17):3443-57. [View Abstract]
  10. Dietschy T, Shevelev I, Pena-Diaz J, et al. p300-mediated acetylation of the Rothmund-Thomson-syndrome gene product RECQL4 regulates its subcellular localization. J Cell Sci. 2009 Apr 15. 122:1258-67. [View Abstract]
  11. Maire G, Yoshimoto M, Chilton-MacNeill S, Thorner PS, Zielenska M, Squire JA. Recurrent RECQL4 imbalance and increased gene expression levels are associated with structural chromosomal instability in sporadic osteosarcoma. Neoplasia. 2009 Mar. 11(3):260-8, 3p following 268. [View Abstract]
  12. Wu J, Capp C, Feng L, Hsieh TS. Drosophila homologue of the Rothmund-Thomson syndrome gene: essential function in DNA replication during development. Dev Biol. 2008 Nov 1. 323(1):130-42. [View Abstract]
  13. Ferrarelli LK, Popuri V, Ghosh AK, Tadokoro T, Canugovi C, Hsu JK, et al. The RECQL4 protein, deficient in Rothmund-Thomson syndrome is active on telomeric D-loops containing DNA metabolism blocking lesions. DNA Repair (Amst). 2013 Jul. 12(7):518-28. [View Abstract]
  14. Gupta S, De S, Srivastava V, Hussain M, Kumari J, Muniyappa K, et al. RECQL4 and p53 potentiate the activity of polymerase ? and maintain the integrity of the human mitochondrial genome. Carcinogenesis. 2014 Jan. 35(1):34-45. [View Abstract]
  15. Lu L, Jin W, Wang LL. Aging in Rothmund-Thomson syndrome and related RECQL4 genetic disorders. Ageing Res Rev. 2017 Jan. 33:30-35. [View Abstract]
  16. Mo D, Zhao Y, Balajee AS. Human RecQL4 helicase plays multifaceted roles in the genomic stability of normal and cancer cells. Cancer Lett. 2018 Jan 28. 413:1-10. [View Abstract]
  17. Popadic S, Nikolic M, Gajic-Veljic M, Bonaci-Nikolic B. Rothmund-Thomson syndrome. The first case with plantar keratoderma and the second with coeliac disease. Acta Dermatovenerol Alp Panonica Adriat. 2006 Jun. 15(2):90-3. [View Abstract]
  18. Otsu U, Moriwaki S, Iki M, Nozaki K, Horiguchi Y, Kiyokane K. Early blistering, poikiloderma, hypohidrosis, alopecia and exocrine pancreatic hypofunction: a peculiar variant of Rothmund-Thomson syndrome?. Eur J Dermatol. 2008 Nov-Dec. 18(6):632-4. [View Abstract]
  19. Zils K, Klingebiel T, Behnisch W, Mueller HL, Schlegel PG, Fruehwald M, et al. Osteosarcoma in patients with Rothmund-Thomson syndrome. Pediatr Hematol Oncol. 2015 Feb. 32 (1):32-40. [View Abstract]
  20. Piquero-Casals J, Okubo AY, Nico MM. Rothmund-thomson syndrome in three siblings and development of cutaneous squamous cell carcinoma. Pediatr Dermatol. 2002 Jul-Aug. 19(4):312-6. [View Abstract]
  21. Howell SM, Bray DW. Amelanotic melanoma in a patient with Rothmund-Thomson syndrome. Arch Dermatol. 2008 Mar. 144(3):416-7. [View Abstract]
  22. Prendiville JS, Fine JD, Esterly NB. Kindler syndrome and epidermolysis bullosa simplex. J Am Acad Dermatol. 1990 Aug. 23(2 Pt 1):327-8. [View Abstract]
  23. Wang LL, Plon SE. Rothmund-Thomson Syndrome. Adam MP, Ardinger HH, Pagon RA, Wallace SE, Bean LJH, Stephens K, Amemiya A. GeneReviews. August 11, 2016. University of Washington, Seattle: 1993.
  24. Larizza L, Roversi G, Verloes A. Clinical utility gene card for: Rothmund-Thomson syndrome. Eur J Hum Genet. 2012 Nov 28. [View Abstract]
  25. Mehollin-Ray AR, Kozinetz CA, Schlesinger AE, Guillerman RP, Wang LL. Radiographic abnormalities in Rothmund-Thomson syndrome and genotype-phenotype correlation with RECQL4 mutation status. AJR Am J Roentgenol. 2008 Aug. 191(2):W62-6. [View Abstract]
  26. Geronemus RG. Treatment of the cutaneous vascular component of the Rothmund-Thomson syndrome. Pediatr Dermatol. 1996 Mar-Apr. 13(2):175. [View Abstract]

Note the poikiloderma and skeletal abnormalities.

Close-up of poikiloderma.

Close-up of poikiloderma.

Note the poikiloderma and skeletal abnormalities.

Close-up of poikiloderma.

Close-up of poikiloderma.