Chromatin refers to the linear composite structure composed of DNA, histones, non-histones, and a small amount of RNA in the interphase nuclei, and is the form in which interphase cells have genetic material. Chromosome refers to the rod-like structure formed by the condensation of chromatin during mitosis or meiosis. In fact, there is no difference in the chemical composition of the two, and the degree of packaging, that is, the configuration, are different forms of genetic material at different stages of the cell cycle. In the cell cycle of eukaryotic cells, most of the time exist in the form of chromatin.
Figure 1. Diagram of chromosome.
In animal cells, chromosomes reach the highest level of compression in the later stages of the chromosome separation process. Chromosomal recombination during meiosis and subsequent sexual reproduction play an important role in genetic diversity. If these structures are incorrectly manipulated by processes called chromosomal instability and translocation, cells may experience mitotic catastrophe. Typically, this will cause the cell to initiate apoptosis leading to its own death, but sometimes mutations in the cell can impede the process, leading to cancer progression. Some people use the term "chromosome" in a broader sense to refer to an individualized portion of chromatin in a cell that is visible or invisible under a light microscope. Others use the concept in a narrow sense, referring to the various parts of chromatin during cell division, which are visible under an optical microscope due to their high height.
Human chromosomes can be divided into two types: autosomes (somatic chromosomes) and sex chromosomes (heterologous chromosomes). Certain genetic traits are related to a person's gender and are transmitted through the sex chromosome. The autosome thus contains the rest of the genetic information. The autosomal and sex chromosomes are identical in replication, mitosis and meiosis. Human cells have 23 pairs of chromosomes (22 pairs of autosomes and a pair of sex chromosomes), that is, there are 46 chromatids per cell. In addition, human cells have hundreds of mitochondrial chromosome copies. Sequencing of the human genome provides a wealth of information about each chromosome. The following table is based on the genomic data compiled by the Sanger Institute's Human Genome Information in the Vertebrate Genome Annotation (VEGA) database. The number of genes is an estimate because it is based in part on genetic prediction. The total chromosome length is also an estimate based on the size of the unsequenced heterochromatin region.
Figure 2. Human chromosomes during metaphase.
Chromosomal aberration refers to the change in the number of normal chromosomes in a cell. Although most chromosomal aberrations have little or no negative impact on human health, some chromosomal aberrations are the leading cause of human genetic disease. For example, Down Syndrome (There are 3 copies of chromosome 21). Chromosomal translocations or chromosomal inversions do not cause disease in carriers, but they may increase the chances of their offspring becoming ill. Abnormal numbers of chromosomes or genomes, also known as aneuploidy, may be fatal to hereditary diseases.
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