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Chromosome abnormality

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(Redirected from Chromosomal aberration)
Not to be confused with Chromatic aberration.

A chromosomal abnormality, chromosomal anomaly, chromosomal aberration, chromosomal mutation, or chromosomal disorder is a missing, extra, or irregular portion of chromosomal DNA.[1][2] These can occur in the form of numerical abnormalities, where there is an atypical number of chromosomes, or as structural abnormalities, where one or more individual chromosomes are altered. Chromosome mutation was formerly used in a strict sense to mean a change in a chromosomal segment, involving more than one gene.[3] Chromosome anomalies usually occur when there is an error in cell division following meiosis or mitosis. Chromosome abnormalities may be detected or confirmed by comparing an individual's karyotype, or full set of chromosomes, to a typical karyotype for the species via genetic testing.

Sometimes chromosomal abnormalities arise in the early stages of an embryo, sperm, or infant.[4] They can be caused by various environmental factors. The implications of chromosomal abnormalities depend on the specific problem, they may have quite different ramifications. Some examples are Down syndrome and Turner syndrome.

Numerical abnormality

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A karyotype of an individual with trisomy 21, showing three copies of chromosome 21.

Maintaining a euploid state, where cells contain the correct number of chromosome sets, is essential for genomic stability. [5] Aneuploidy, characterized by an abnormal number of chromosomes, occurs when an individual is missing a chromosome from a pair (monosomy) or has an additional chromosome (trisomy), and it can be either full, involving a whole chromosome, or partial, where only part of a chromosome is missing or added.[6][7][8] Aneuploidy may arise from meiosis segregation errors such as nondisjunction, premature disjunction, or anaphase lag during meiosis I or II. [9] For aneuploidy, nondisjunction, the most frequent error, particularly in oocyte formation, occurs when replicated chromosomes fail to separate properly, leading to germ cells with an extra or missing chromosome.[9] Additionally, polyploidy occurs when cells contain more than two sets of chromosomes. [10] Polyploidy encompasses various forms, including triploid (three sets of chromosomes) and tetraploid (four sets of chromosomes). [11] Tetraploidy often arises from developmental errors during mitosis, such as cytokinesis failure, endoreplication, mitotic slippage, and cell fusion. These errors can subsequently lead to aneuploidy. [11]

A karyotype of an individual with Turner Syndrome, where there is only a single X chromosome.

Aneuploidy can occur with sex chromosomes or autosomes.[citation needed] Rather than having monosomy, or only one copy, the majority of aneuploid people have trisomy, or three copies of one chromosome.[citation needed] An example of trisomy in humans is Down syndrome, which is a developmental disorder caused by an extra copy of chromosome 21; the disorder is therefore also called "trisomy 21".[12] An example of monosomy in humans is Turner syndrome, where the individual is born with only one sex chromosome, an X.[13]

Sperm aneuploidy

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Exposure of males to certain lifestyle, environmental and/or occupational hazards may increase the risk of aneuploid spermatozoa.[14] In particular, risk of aneuploidy is increased by tobacco smoking,[15][16] and occupational exposure to benzene,[17] insecticides,[18][19] and perfluorinated compounds.[20] Increased aneuploidy is often associated with increased DNA damage in spermatozoa.

Structural abnormalities

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The three major single-chromosome mutations: deletion (1), duplication (2) and inversion (3).
The two major two-chromosome mutations: insertion (1) and translocation (2).

When the chromosome's structure is altered, this can take several forms:[21]

  • Deletions: A portion of the chromosome is missing or has been deleted. Known disorders in humans include Wolf–Hirschhorn syndrome, which is caused by partial deletion of the short arm of chromosome 4; and Jacobsen syndrome, also called the terminal 11q deletion disorder.
  • Duplications: A portion of the chromosome has been duplicated, resulting in extra genetic material. Known human disorders include Charcot–Marie–Tooth disease type 1A, which may be caused by duplication of the gene encoding peripheral myelin protein 22 (PMP22) on chromosome 17.
  • Inversions: A portion of the chromosome has broken off, turned upside down, and reattached, therefore the genetic material is inverted.
  • Insertions: A portion of one chromosome has been deleted from its normal place and inserted into another chromosome.
  • Translocations: A portion of one chromosome has been transferred to another chromosome. There are two main types of translocations:
  • Rings: A portion of a chromosome has broken off and formed a circle or ring. This happens with or without the loss of genetic material.
  • Isochromosome: Formed by the mirror image copy of a chromosome segment including the centromere.

Chromosome instability syndromes are a group of disorders characterized by chromosomal instability and breakage. They often lead to an increased tendency to develop certain types of malignancies.

Inheritance

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Autosomal dominant and autosomal recessive inheritance patterns

Constitutional chromosome abnormalities arise during gametogenesis or embryogenesis, affecting a significant proportion of an organism’s cells. [22] These inherited abnormalities most commonly occur as errors in the egg or sperm, meaning the anomaly is present in every cell of the body. [23] Factors such as maternal age and environmental influences contribute to the occurrence of these genetic errors. [23] Offspring inherit two copies of each gene, one from each parent, and mutations (often caused by disease) may be passed down through generations. [24] The diseases that follow a single-gene inheritance pattern are relatively rare but affect millions of individuals. [24] This can be represented through the Mendelian inheritance patterns:

X-linked dominant inheritance patterns, differing between maternal and paternal origin, on offspring
  • Autosomal dominant: Where at least one affected parent passes the mutation, and the condition appears in every generation. Examples include Huntington’s disease, achondroplasia, and neurofibromatosis. [25]
X-linked recessive inheritance patterns, differing between maternal and paternal origin, on offspring
  • Autosomal recessive: Both parents are carriers of the mutation (though it may not appear in every generation). The disorder manifests only when both copies of the inherited gene are mutated. Examples include Tay-Sachs disease, sickle cell anemia, and cystic fibrosis. [25]
  • X-linked inheritance: Mutated X chromosomes may be inherited in a dominant or recessive manner. Within X-linked recessive inheritance, males are more frequently affected than females. Since males have only one X chromosome, they will express the disease if that single X carries the mutation. In contrast, females, with two X chromosomes, must inherit the mutated gene from both parents for the disorder to manifest. X-linked dominant diseases can affect both males and females; a father with an X-linked dominant trait passes it only to his daughters, while a mother can pass the trait to both sons and daughters. [26]
  • Mitochondrial inheritance: This pattern affects both males and females but is passed only through the mother, as all mitochondria in offspring are inherited from the mother. Examples include Leber’s hereditary optic neuropathy and Kearns-Sayre syndrome. [27]

Given these patterns of inheritance, chromosome studies are often conducted on parents when a child is found to have a chromosomal anomaly. If the parents do not exhibit the abnormality, it was not inherited but may be passed down in subsequent generations. [citation needed]

Chromosomal abnormalities can also arise from de novo mutations within an individual. [28] De novo mutations are spontaneous, somatic mutations that occur without prior inheritance, and they can emerge at various stages of life, including during the parental germline, embryonic or fetal development, or later in life due to aging. [29] These mutations may occur during gametogenesis or postzygotically, resulting in new mutations that appear in a single generation without prior evidence of mutation in the parental chromosomes. [30] Approximately 7% of de novo mutations are present as high-level mosaic mutations. [30] Genetic mosaicism, which refers to a post-zygotic mutation, occurs when an individual possesses two or more genetically distinct cell populations derived from a single fertilized egg. [30][31] This can lead to chromosomal abnormalities, and these mutations may be present in somatic cells, germ cells, or both, in the case of gonosomal mosaicism, where mutations exist in both somatic and germline cells. [29] Somatic mosaicism involves multiple cell lineages in somatic cells, while germline mosaicism occurs in multiple lineages within germline cells, allowing the mutation to be passed to offspring. [31] An example of a chromosomal abnormality resulting from genetic mosaicism is Turner syndrome. [31]

Acquired chromosome abnormalities

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Acquired chromosomal abnormalities represent genetic alterations that manifest during an individual's lifetime, as opposed to being inherited from their parents.[32] These modifications predominantly occur within somatic cells and are characterized by their non-heritable nature. [32] Typically, they arise from mutations that transpire during the process of DNA replication or as a consequence of exposure to various environmental factors [33]. In contrast to constitutional chromosomal abnormalities, which are present at birth, acquired abnormalities occur during adulthood and are confined to specific clones of cells, thereby inhibiting their distribution throughout the body. [33]

The development of chromosomal abnormalities and malignancies can be attributed to environmental exposures or may occur spontaneously during DNA replication. [34][35] Spontaneous replication errors typically occur due to DNA polymerase synthesizing new polynucleotides while evading proofreading functions, leading to mismatches in base pairing. [34] Throughout a human's lifetime, individuals may encounter mutagens (which are agents that induce mutations) that lead to chromosomal mutations. These mutations arise when a mutagen interacts with parental DNA, typically affecting one strand, resulting in structural alterations that hinder the successful base pairing with the modified nucleotide [34]. Consequently, daughter molecules inherit these mutations, which may further accumulate additional damage, subsequently being passed down to the next generations of cells. [36] Mutagens can be classified as physical, chemical, or biological. Common chemical mutagens include base analogs (molecules that resemble nitrogenous bases), deaminating agents (which remove amino groups), alkylating agents, and intercalating agents. [34] The most prevalent sources of physical mutagens are exposure to UV radiation, which induces dimerization of adjacent pyrimidine bases, and ionizing radiation, which typically causes point mutations, insertions, or deletions. [34] Heat can also function as a mutagen by promoting the cleavage of the β-N-glycosidic bond, which connects the base to the sugar part of the nucleotide, through water-induced processes. [34] Biological mutagens are introduced through exposure to viruses, bacteria, and/or transposons and insertion sequences (IS). [37] Transposons and IS can move through DNA by 'jumping,' disrupting the functionality of chromosomal DNA. The insertion of viral DNA can lead to genetic disruption, while bacteria may produce reactive oxygen species (ROS) that cause inflammation and DNA damage, resulting in decreased repair efficiency. [37]

Sporadic cancers are those that develop due to mutations that are not inherited; in these cases, normal cells gradually accumulate mutations and cellular damage. [38] Most cancers, if not all, could cause chromosome abnormalities,[39] with either the formation of hybrid genes and fusion proteins, deregulation of genes and overexpression of proteins, or loss of tumor suppressor genes (see the "Mitelman Database" [40] and the Atlas of Genetics and Cytogenetics in Oncology and Haematology,[41]). Approximately 90% of cancers exhibit chromosomal instability (CIN), characterized by the frequent gain or loss of entire chromosome segments. [42] This phenomenon contributes to tumor aneuploidy and intra-tumor heterogeneity, which are commonly observed in most human cancers. [42] [43] For instance, certain consistent chromosomal abnormalities can turn normal cells into a leukemic cell such as the translocation of a gene, resulting in its inappropriate expression.[44]

DNA damage during spermatogenesis

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During the mitotic and meiotic cell divisions of mammalian gametogenesis, DNA repair is effective at removing DNA damages.[45] However, in spermatogenesis the ability to repair DNA damages decreases substantially in the latter part of the process as haploid spermatids undergo major nuclear chromatin remodeling into highly compacted sperm nuclei. As reviewed by Marchetti et al.,[46] the last few weeks of sperm development before fertilization are highly susceptible to the accumulation of sperm DNA damage. Such sperm DNA damage can be transmitted unrepaired into the egg where it is subject to removal by the maternal repair machinery. However, errors in maternal DNA repair of sperm DNA damage can result in zygotes with chromosomal structural aberrations.[citation needed]

Melphalan is a bifunctional alkylating agent frequently used in chemotherapy. Meiotic inter-strand DNA damages caused by melphalan can escape paternal repair and cause chromosomal aberrations in the zygote by maternal misrepair.[46] Thus both pre- and post-fertilization DNA repair appear to be important in avoiding chromosome abnormalities and assuring the genome integrity of the conceptus.[citation needed]

Detection

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Depending on the information one wants to obtain, different techniques and samples are needed.[citation needed]

Nomenclature

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  • Three chromosomal abnormalities with ISCN nomenclature, with increasing complexity: (A) A tumour karyotype in a male with loss of the Y chromosome, (B) Prader–Willi Syndrome i.e. deletion in the 15q11-q12 region and (C) an arbitrary karyotype that involves a variety of autosomal and allosomal abnormalities.[47]
    Three chromosomal abnormalities with ISCN nomenclature, with increasing complexity: (A) A tumour karyotype in a male with loss of the Y chromosome, (B) Prader–Willi Syndrome i.e. deletion in the 15q11-q12 region and (C) an arbitrary karyotype that involves a variety of autosomal and allosomal abnormalities.[47]
  • Human karyotype with annotated bands and sub-bands as used for the nomenclature of chromosome abnormalities. It shows dark and white regions as seen on G banding. Each row is vertically aligned at centromere level. It shows 22 homologous autosomal chromosome pairs, both the female (XX) and male (XY) versions of the two sex chromosomes, as well as the mitochondrial genome (at bottom left).
    Human karyotype with annotated bands and sub-bands as used for the nomenclature of chromosome abnormalities. It shows dark and white regions as seen on G banding. Each row is vertically aligned at centromere level. It shows 22 homologous autosomal chromosome pairs, both the female (XX) and male (XY) versions of the two sex chromosomes, as well as the mitochondrial genome (at bottom left).
Further information: Karyotype

The International System for Human Cytogenomic Nomenclature (ISCN) is an international standard for human chromosome nomenclature, which includes band names, symbols and abbreviated terms used in the description of human chromosome and chromosome abnormalities. Abbreviations include a minus sign (-) for chromosome deletions, and del for deletions of parts of a chromosome.[48]

See also

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References

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