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Chromosome Instability in a Calf with Amelia of Thoracic Limbs

Abstract

We report here on a case of a Holstein-Friesian male calf with the congenital total absence of thoracic limbs (amelia). Cytogenetic study showed a high rate of chromosome instability, represented by chromosome or chromatid breaks and gaps in 46% of the analyzed metaphase spreads. Moreover, 12% of the spreads appeared to be polypolid. The number of micronuclei also was significantly higher when compared to control animals. This paper discusses the association between chromosome instability and limb malformation.

Key words: Amelia; cattle; chromosome instability; congenital disorder; limb malformation; micronuclei.

Amelia—the total absence of limbs—is a rare congenital malformation diagnosed in domestic animal newborns. In cattle, only cases of hemimelia (the absence of a portion of a limb) and deformities of hind limbs have been reported recently.^11,22

The etiology of limb malformation includes hereditary factors, environmental factors, or a combination of both. In humans, some limb anomalies are inherited, and genes responsible for the anomalies have been identified.^12,20 There also are reports indicating that chromosomal aberrations are associated with congenital limb malformations.¹³ In the present study we describe a case of a Holstein-Friesian newborn male calf with a total absence of thoracic limbs associated with chromosomal instability.

A newborn male Holstein-Friesian calf lacking thoracic limbs was subjected to clinical examination (Fig. 1). Thoracic limbs were not present, and scapular spines were poorly palpable. During external examination other anomalies were not detected. The thorax and ribs had normal constitution. The head, trunk, and pelvic limbs were normally developed. The animal could take food normally, but at day 10 the calf was euthanatized.

View larger version (177K): [in this window] [in a new window]   Fig. 1 Male calf without thoracic limbs.

Postmortem examination revealed the presence of chondral scapulas and a lack of distal skeleton. Soft tissues of the thoracic limbs and the latissimus muscle of the back were not present. X-ray examination confirmed only a shadow of chondral scapulas on the level of spinous processes of thoracic vertebrae (Fig. 2).

View larger version (128K): [in this window] [in a new window]   Fig. 2 Radiograph of the lower part of the neck and upper part of the chest of the amelic male calf.

View larger version (88K): [in this window] [in a new window]   Fig. 3 Cytogenetic preparations obtained from in vitro–cultured lymphocytes of the amelic calf: Fig. 3A. Polyploid spread, Giemsa staining; Fig. 3B. Chromatid break (arrow) in a small autosome, Giemsa staining; Fig. 3C. Chromatid break (arrow) in the X chromosome, Giemsa staining; and Fig. 3D. Normal metaphase spread, C-banding, sex chromosomes are indicated (arrows). Bar = 10 µm.

Analysis of micronuclei frequency in lymphocyte cultures derived from the calf also was performed (Table 1, Fig. 4). It was shown that the number of nuclei with at least one micronucleus was higher (15/1,000) compared with lymphocyte cultures carried out under the same conditions for 3 healthy bulls (on average, 3/1,000).

View larger version (126K): [in this window] [in a new window]   Fig. 4 Cytogenetic preparation obtained from in vitro–cultured lymphocytes of the amelic calf: a single micronucleus connected with the nucleus (Fig. 4A, B, D), and 2 micronuclei localized in a close vicinity of the nucleus (Fig. 4C). Bar = 10 µm.

Increased genomic instability also was connected to limb malformations. Spontaneous chromosomal breakage was reported in a child with limb defects.² Chromosome instability also was diagnosed in a calf affected by congenital malformation (lack of the distal left anterior leg and right anterior leg ended with a hook-shaped, naillike structure); namely, high rates of structural chromosome aberrations and increased yields of sister chromatid exchanges were reported.⁴ Another case of a malformed calf affected with polymelia and a high incidence of chromosome breaks was described recently.¹⁵ On the other hand, chromosome instability can be analyzed in relation to the distribution of fragile sites, which are divided into two categories: rare and common.^1,19 These sites are expressed under specific conditions during lymphocyte culture. The common ones are induced by mutagens, such as aphidicolin, whereas the rare ones are folate sensitive. An association between the rare fragile and abnormal phenotype was reported in a girl with brachydactyly and a short stature.¹⁸ Mutagen-induced chromosome instability also was analyzed in cattle, and the most expressive fragile sites in cows were observed in chromosomes 1 and X.³ The fragile site in the X chromosome is present in the same chromosome band (Xq24) as the chromatid break in the amelic calf.

Since the mechanism of limb development is common in higher vertebrates, mutations of the homeotic and other genes should also be considered as potential causes of limb malformations.^5,12 It was reported recently that a mutation of the WNT3 gene causes tetra-amelia.¹⁴ In the present case a gene mutation seems to be unlikely, because pedigree data did not indicate an inherited background of this abnormality.

Chromosome instability similar to that reported in this paper was found in sheep exposed to dioxins during pasturage.⁹ It is also very well documented in humans that a high incidence of limb deformity in newborns was an effect of thalidomide.⁷ Genotoxicity also can be evaluated with the use of the micronucleus test. In the present study no information about the exposure of the pregnant cow to teratogens was available. However, the increased micronuclei frequency observed in the studied animal indicates that an environmental cause of the observed malformation cannot be excluded.

Acknowledgements

IS is a holder of the Young Scientists Fellowship (Foundation for Polish Science, contract 88/2004).

References

1. Arlt MF, Casper AM, Glover TW. Common fragile sites. Cytogenet Genome Res 100:92–100, 2003[CrossRef][ISI][Medline]
2. Brewer CM, Grace E, Stark GD, Gregory DW, Howell RT, Fitzpatrick DR. Genomic instability associated with limb defects: case report and review of the literature. Clin Dysmorphol 6:99–109, 1997[ISI][Medline]
3. Danielak-Czech B, Slota E. Mutagen-induced chromosome instability in farm animals. J Anim Feed Sci 13:257–267, 2004
4. Di Berardino D, Iannuzzi L, Fregola A, Matassino D. Chromosome instability in a calf affected by congenital malformation. Vet Rec 112:429–432, 1983[Abstract]
5. Goodman FR. Limb malformations and human HOX genes. Am J Med Genet 112:256–265, 2002[CrossRef][ISI][Medline]
6. Gotze A, Krebs P, Stumm M, Wieacker P, Allhoff EP. Trisomy 8 mosaicism in a patient with tetraamelia. Am J Med Genet 86:497–498, 1999[CrossRef][ISI][Medline]
7. Holmes LB. Teratogen-induced limb defects. Am J Med Genet 112:297–303, 2002[CrossRef][ISI][Medline]
8. Hou JW, Wang TR. Amelia, dextrocardia, asplenia, and congenital short bowel in deleted ring chromosome 4. J Med Genet 33:879–881, 1996[Abstract]
9. Iannuzzi L, Perucatti A, Di Meo GP, Polimeno F, Ciotola F, Incarnato D, Peretti V, Caputi-Jambrenghi A, Pecoraro A, Manniti F, D'Alessandro A, Vonghia G. Chromosome fragility in two sheep flocks exposed to dioxins during pasturage. Mutagenesis 19:355–359, 2004[Abstract/Free Full Text]
10. International System for Chromosome Nomenclature of Domestic Bovids (ISCNB 2000). Cytogenet Cell Genet 92:283–299, 2001[CrossRef][Medline]
11. Lapointe JM, Lachance S, Steffen DJ. Tibial hemimelia, meningocele and abdominal hernia in Shorton Cattle. Vet Pathol 37:508–511, 2000[Abstract/Free Full Text]
12. Manouvrier-Hanu S, Holder-Espinasse M, Lyonnet S. Genetics of limb anomalies in humans. Trends Genet 15:409–417, 1999[CrossRef][ISI][Medline]
13. Morey MA, Higgins RR. Ectro-amelia syndrome associated with an interstitial deletion of 7q. Am J Med Genet 35:95–99, 1990[CrossRef][ISI][Medline]
14. Niemann S, Zhao C, Pascu F, Stahl U, Aulepp U, Niswander L, Weber JL, Muller U. Homozygous WNT3 mutation causes tetra-amelia in a large consanguineous family. Am J Hum Genet 74:558–563, 2004[CrossRef][ISI][Medline]
15. Nowacka J, Urbaniak K, Antosik P, Jaskowski JM, Frackowiak H, Switonski M. Polymelia associated with frequent chromosome break in a heifer. Vet Rec in press, 2006.
16. Ohro Y, Suzuki Y, Tsutsumi Y, Ogata T. Female external genitalia, absent uterus, and probable agonadism in a 46,XY infant with bilateral upper amelia. Clin Genet 54:52–55, 1998[ISI][Medline]
17. Pawlowitzki IH, Cenani A, Frischibier HJ. Autosomal monosomy (45, XX, C–) in a human embryo with total amelia and further malformations. Clin Genet 4:193–202, 1973[ISI][Medline]
18. Stoll C, Roy-Doray B, Dott B, Alembik Y. Brachydactyly and short stature in a mother and her daughter with a fragile site at 16q22. Genet Couns 8:115–120, 1997[ISI][Medline]
19. Sutherland GR. Rare fragile sites. Cytogenet Genome Res 100:77–84, 2003[CrossRef][ISI][Medline]
20. Tickle C. Molecular basis of vertebrate limb patterning. Am J Med Genet 112:250–255, 2002[CrossRef][ISI][Medline]
21. Van der Berg DJ, Francke U. Roberts syndrome: a review of 100 cases and a new rating system for severity. Am J Med Genet 47:1104–1123, 1993[CrossRef][ISI][Medline]
22. Vermunt JJ, Burbidge HM, Thompson KG. Unusual congenital deformities of the lower limb in two calves. N Z Vet J 48:192–194, 2000[ISI][Medline]

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