Genomic catastrophe causes developmental delay, cognitive disorders
Using a diversity of DNA sequencing and human genome analytic techniques, researchers led by Baylor College of Medicine have identified some cases of developmental delay or cognitive disorders associated with a sudden chromosomal catastrophe that occurred early in development, perhaps during cell division when DNA is replicated.
In a report in the journal Cell, Dr. Weimin Bi, assistant professor of molecular and human genetics, Dr. James R.Lupski, vice chair of molecular and human genetics, both at BCM, first author Pengfei Liu, a graduate student in Lupski’s laboratory, and their many clinical collaborating colleagues describe the analysis of the DNA of 17 patients who were referred to BCM because they had unexplained developmental problems.
“Four were very complex,” said Liu. “One had 18 rearrangements in one chromosome. It was beyond our imagination.”
About that time, a group of British researchers led by the Wellcome Trust Sanger Institute published another paper in Cell describing massive genomic rearrangements in cancer that they believe emanated from a single catastrophic event.
Lupski, Bi and Liu wondered if a similar situation had occurred in their patients, whose rearrangements occurred early in the germ line – the cells that produce eggs and sperm. The events that had occurred in the genetic code of these patients shared striking similarities to the findings in the patients with cancer.
“First, the patients have many duplications and deletions,” said Lupski, a pioneer in identifying and understanding copy number variation, changes that occur in the genome that either duplicate or delete genes, changing their expression with profound effects on the individual patients.
“We used comparative genomic array hybridization, FISH (fluorescent in situ hybridization, which can tell a person how many copies of a certain chromosome exist in each cell) and other techniques to demonstrate that this ‘catastrophe’ phenomenon exists in the genomes of these patients,” said Liu. “This chromosomal catastrophe occurs not only in cancer but can also occur in different developmental tissues. They may occur in the germ line, as in our case, or in the somatic cells. In one case, the patient had this complex rearrangement and the mother also has it, but the rearrangement occurs in only a subset of her cells. It occurred in the mother during development and she then transmitted the rearrangement to the child.”
“We see extensive complexity in the rearrangement,” said Lupski. The researchers who wrote the cancer paper saw even more complex changes.
However, when such extreme changes occur in the chromosomes of developing embryos, this could potentially disrupt development resulting in “death before birth.” The Baylor researchers propose that this accounts for the differences in the two groups, i.e. degree of complexity observed with cancer versus in subjects with cognitive disabilities, but they provide evidence that it is likely the same mechanisms are involved in the chromosomal catastrophes. The genomic changes they describe occur early in the development. The cancer changes occur in the cells of people who are often adults.
“We are looking for the mechanisms that cause this catastrophe,” said Lupski. “We are dealing with pure rearrangement. The whole body has it, not just a subset of cancerous cells within a growing tumor.”
In their work, the team saw features that seemed to indicate that the catastrophe may have occurred as a result of a single event involving DNA replication – the process during cell division in which the pattern of DNA is copied for use in the new cell. If that replication process misfires, then the DNA is not copied accurately and the resulting cell is abnormal.
The developmental disorders the BCM team studies are those that can be caused by mutation in one of many potential genes.
“A combination of effects on multiple genes may be responsible for some subset of disorders,” said Lupski. “You can interrupt one gene, delete another gene, make three copies of another gene; a single mutational event, but a potential multigenic effect.”
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Others who took part in this research include Ayelet Erez, Sandesh C. Sreenath Nagamani, Shweta U. Dhar, Katarzyna E. Kołodziejska, Avinash V. Dharmadhikari, M. Lance Cooper, Joanna Wiszniewska, Feng Zhang, Marjorie A. Withers, Carlos A. Bacino, Seema R. Lalani, Fernando Scaglia, Lane Strathearn, Sung-Hae L. Kang, Ankita Patel, Sau Wai Cheung, P. J. Hastings, and Paweł Stankiewicz all of BCM; Luis Daniel Campos-Acevedo and Dolores Hernández-Almaguer of Departamento de Genética, Hospital Universitario, Monterrey, México; Mauricio R. Delgado of Texas Scottish Rite Hospital in Dallas; Debra Freedenberg of Vanderbilt in Nashville, TN.; Adolfo Garnica of St. Francis Hospital in Tulsa, OK.; Theresa A. Grebe of Phoenix Children’s Hospital; LaDonna Immken of Specially for Children in Austin, TX.; Scott D. McLean of San Antonio Military Medical Center; Hope Northrup of The University of Texas Medical School at Houston, and Pamela Trapane of Children’s Hospital of Wisconsin in Milwaukee.
Funding for this work came from the National Institute of Neurological Disorders and Stroke, the National Institutes of General Medical Science, the Baylor College of Medicine Intellectual and Developmental Disabilities Research Center, The Eunice Kennedy Shriver National Institute of Children Health & Human Development, the Osteogenesis Imperfecta Foundation and the National Urea Cycle Foundation.
Dr. Lupski holds the Cullen Endowed Chair in Molecular Genetics.
For more information on basic research at Baylor College of Medicine, please go to From the Labs at Baylor College of Medicine College of Medicine.
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Contact: Glenna Picton
713-798-4710
Baylor College of Medicine