Breakpoint analysis of the recurrent constitutional t(8;22)(q24.13;q11.21) translocation

Mishra, Divya; Kato, Takema; Inagaki, Hidehito; Kosho, Tomoki; Wakui, Keiko; Kido, Yasutoshi; Sakazume, Satoru; Taniguchi‐Ikeda, Mariko; Morisada, Naoya; Iijima, Kazumoto; Fukushima, Yoshimitsu; Emanuel, Beverly S.; Kurahashi, Hiroki

doi:10.1186/s13039-014-0055-x

Cited by 12 publications

(30 citation statements)

References 33 publications

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“…Data Sources. DNA sequences from acquired congenital disorders were from published whole genome sequences at chromosome breakpoints and rearrangement sites [1][2][3] . Comparison to multiple databases of microbial sequences determined whether there was significant human homology.…”

Section: Methodsmentioning

confidence: 99%

“…Emphasis was on cases with strong evidence that a particular human chromosome rearrangement was pathologic for the congenital disorder. Patients in the 3 major studies [1][2][3] used in this analysis were 98 females and 144 males.…”

Section: Methodsmentioning

confidence: 99%

“…Large amounts of foreign DNA present during human meiosis with its many double strand breaks during the most active period of recombination produce defective gametes. Errors in spermatogenesis underlie a prevalent and recurrent gene rearrangement that causes intellectual disability, and dysmorphism (Emanuel syndrome) 2 . In contrast, recombination in ova occurs in fetal life and then meiosis is arrested until puberty 51 .…”

Section: A Model For Infection Interference In Neurodevelopmentmentioning

confidence: 99%

“…As the nervous system develops, tion of the neurologic system. Based on DNA sequence analyses, some chromosome rearrangements have been identified as causing individual congenital disorders because they disrupt genes essential for normal development [1][2][3] . There is poor understanding and no effective treatment for many of these overwhelming abnormalities.…”

Section: Introductionmentioning

confidence: 99%

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A Genome Model Linking Birth Defects to Infections

Friedenson

2019

Preprint

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The purpose of this study was to test the hypothesis that infections are linked to chromosomal anomalies that cause neurodevelopmental disorders. In children with disorders in the development of their nervous systems, chromosome anomalies known to cause these disorders were compared to microbial DNA, including known teratogens. Genes essential for neurons, lymphatic drainage, immunity, circulation, angiogenesis, cell barriers, structure, epigenetic and chromatin modifications were all found close together in polyfunctional clusters that were deleted or rearranged in neurodevelopmental disorders. In some patients, epigenetic driver mutations also changed access to large chromosome segments. These changes account for immune, circulatory, and structural deficits that accompany neurologic deficits. Specific and repetitive human DNA encompassing large deletions matched infections and passed rigorous artifact tests. Deletions of up to millions of bases accompanied infection-matching sequences and caused massive changes in the homologies to foreign DNAs. In data from three independent studies of private, familial and recurrent chromosomal rearrangements, massive changes in homologous microbiomes were found and may drive rearrangements and encourage pathogens. At least one chromosomal anomaly was found to consist of human DNA fragments with a gap that corresponded to a piece of integrated foreign DNA. Microbial DNAs that match repetitive or specific human DNA segments are thus proposed to interfere with the epigenome and highly active recombination during meiosis, driven by massive changes in the homologous microbiome. Abnormal recombination in gametes produces zygotes containing rare chromosome anomalies which cause neurologic disorders and non-neurologic signs. Neurodevelopmental disorders may be examples of assault on the human genome by foreign DNA at a critical stage. Some infections may be more likely tolerated because they resemble human DNA segments. Further tests of this model await new technology.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: A Model For Infection Interference In Neurodevelopmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Genome Model Linking Birth Defects to Infections

Friedenson

2019

Preprint

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“…A significant advance in genome sequence level resolution of balanced cytogenetic abnormalities greatly improves the ability to document changes in regulation and dosage for genes critical to the function of the neurologic system. Based on DNA sequence analyses, some chromosome rearrangements have been identified as causing individual congenital disorders because they disrupt genes essential for normal development [1][2][3] .…”

Section: Introductionmentioning

confidence: 99%

Parental infections disrupt clustered genes encoding related functions required for nervous system development in newborns

Friedenson¹

2018

Preprint

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The purpose of this study was to understand the role of infection in the origin of chromosomal anomalies linked to neurodevelopmental disorders. In children with disorders in the development of their nervous systems, chromosome anomalies known to cause these disorders were compared to viruses and bacteria including known teratogens. Results support the explanation that parental infections disrupt elaborate multi-system gene coordination needed for neurodevelopment. Genes essential for neurons, lymphatic drainage, immunity, circulation, angiogenesis, cell barriers, structure, and chromatin activity were all found close together in polyfunctional clusters that were deleted in neurodevelopmental disorders. These deletions account for immune, circulatory, and structural deficits that accompany neurologic deficits. In deleted gene clusters, specific and repetitive human DNA matched infections and passed rigorous artifact tests. In some patients, epigenetic driver mutations were found and may be functionally equivalent to deleting a cluster or changing topologic chromatin interactions because they change access to large chromosome segments. In three families, deleted DNA sequences were associated with intellectual deficits and were not included in any database of genomic variants. These sequences were thousands of bp and unequivocally matched foreign DNAs. Analogous homologies were also found in chromosome anomalies of a recurrent neurodevelopmental disorder. Viral and bacterial DNAs that match repetitive or specific human DNA segments are thus proposed to interfere with highly active break repair during meiosis; sometimes delete polyfunctional clusters, and disable epigenetic drivers. Mis-repaired gametes produce zygotes containing rare chromosome anomalies which cause neurologic disorders and accompanying nonneurologic signs. Neurodevelopmental disorders may be examples of assault on the human genome by foreign DNA with some infections more likely tolerated because they resemble human DNA segments. Further tests of this model await new technology.

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