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Genetic recombination aka genetic recombination biology reshuffling is the production of offspring with combinations of traits that differ from those found in either parent. In eukaryotesgenetic recombination during meiosis can lead to a novel set of genetic information that can be passed on from the parents to the offspring.
Most recombination is naturally occurring. During meiosis in eukaryotes, genetic recombination involves the genetic recombination biology of homologous chromosomes. This may be followed by information transfer between the chromosomes. The information transfer may occur without physical exchange a section of genetic material is copied from one chromosome to another, without the donating chromosome being changed see SDSA pathway in Figure ; or by the breaking and rejoining of DNA strands, which forms new molecules of DNA see DHJ pathway in Figure.
Recombination may also occur during mitosis in eukaryotes where it ordinarily involves the two sister chromosomes formed after chromosomal replication. In this case, new combinations of alleles genetic recombination biology not produced since the sister chromosomes are usually identical.
In meiosis and mitosis, recombination occurs between similar molecules of DNA homologs. In meiosis, non-sister homologous chromosomes pair with each other so that recombination characteristically occurs between non-sister homologues.
In both meiotic and mitotic cells, recombination between homologous chromosomes is a common mechanism used in DNA repair. Genetic recombination and recombinational DNA repair genetic recombination biology occurs genetic recombination biology bacteria and archaeawhich use asexual reproduction. Recombination can be artificially induced in laboratory in vitro settings, producing recombinant DNA for purposes including vaccine development.
V D J recombination in organisms with an adaptive immune system is a type of site-specific genetic recombination that helps genetic recombination biology cells rapidly diversify to recognize and adapt to new pathogens.
During meiosis, synapsis genetic recombination biology pairing of homologous chromosomes ordinarily precedes genetic recombination. Genetic recombination is catalyzed by many different enzymes. Recombinases are key enzymes that catalyse the strand transfer step during recombination. In yeast and other eukaryotic organisms there are two recombinases required genetic recombination biology repairing DSBs.
In the archaea, the ortholog of the bacterial RecA protein is RadA. In eukaryotes, recombination during meiosis is facilitated by chromosomal crossover. The crossover process leads to offspring having different combinations of genes from those of their parents, and can occasionally produce new chimeric alleles. The shuffling of genes brought about by genetic recombination produces increased genetic variation.
It also allows genetic recombination biology reproducing organisms to avoid Muller's ratchetin which the genomes of an asexual population accumulate genetic deletions in an irreversible manner. Chromosomal crossover involves recombination between the paired chromosomes inherited from each of one's parents, generally occurring during meiosis.
During prophase I pachytene stage the four available chromatids are in tight formation with one another. While in this formation, homologous sites on two chromatids can closely pair with one another, and may exchange genetic information. Because recombination can occur with small probability at any location along chromosome, the frequency of recombination between two locations depends on the distance separating them.
Therefore, for genes sufficiently distant on the same chromosome, the amount of crossover is high enough to destroy the correlation between alleles. Tracking the movement of genes resulting from crossovers has proven quite useful to geneticists.
Because two genes that are close together are less likely to become separated than genes that are farther apart, geneticists can deduce roughly how far apart two genes are on a chromosome if they know the frequency of the crossovers. Geneticists can also use this method to infer the presence of certain genes. Genes that typically stay together during recombination are said to be linked. One gene in a linked pair can sometimes be used as a marker to deduce the presence of another gene.
This is typically used in order to detect the presence of a disease-causing gene. The recombination frequency between two loci observed is the crossing-over value. It is the frequency of crossing over between two linked gene loci markersand depends on the mutual distance of the genetic loci observed.
For any fixed set of genetic and environmental genetic recombination biology, recombination in a particular region of a linkage structure chromosome tends to be constant, and the same is then true for the crossing-over value which is used in the production of genetic maps.
In gene genetic recombination biology, a section of genetic material is copied from one chromosome to another, without the donating chromosome being changed. Gene conversion occurs at high frequency at the actual site of the recombination event during meiosis.
Gene conversion has often been studied genetic recombination biology fungal crosses  where the 4 products of individual meioses can be conveniently observed. Gene conversion events can be distinguished as deviations in an individual meiosis from the normal 2: Recombination can occur between DNA sequences that contain no sequence homology. This can cause chromosomal translocationssometimes leading to cancer. B cells of the immune system perform genetic recombination, called immunoglobulin class switching.
It is a biological mechanism that changes an antibody from one class to another, for example, from an isotype called IgM to an isotype called Genetic recombination biology. In genetic engineeringrecombination can also refer to artificial and deliberate recombination of disparate pieces of Genetic recombination biology, often from different organisms, creating what genetic recombination biology called recombinant DNA.
A prime example genetic recombination biology such a use of genetic recombination is gene targetingwhich can be used to add, delete or otherwise change an organism's genes. This technique is important to biomedical researchers as it allows them to study the effects of specific genes.
Techniques based on genetic recombination are also applied in protein engineering to develop new proteins of biological interest. During both mitosis and meiosis, DNA damages caused by a variety of exogenous agents e.
UV lightX-rayschemical cross-linking agents can be repaired by homologous recombinational repair HRR. In humans and rodents, deficiencies in the gene products necessary for HRR during meiosis cause infertility. In bacteria, transformation is a process of gene transfer that ordinarily occurs between individual cells of the same bacterial species. Transformation involves integration of donor DNA into the recipient chromosome by recombination.
When two or more viruses, each containing lethal genomic damages, infect the genetic recombination biology host cell, the virus genomes can often pair with each other and undergo HRR to produce viable genetic recombination biology. This process, referred to as multiplicity reactivation, has been studied in lambda and T4 bacteriophages as well as in several pathogenic viruses. In the case of pathogenic viruses, multiplicity reactivation may be an adaptive benefit to the virus since it allows the repair of DNA damages caused by exposure to the oxidizing environment produced during host infection.
Molecular models of meiotic recombination have evolved over the years as relevant evidence accumulated. A major incentive for developing a fundamental understanding of the mechanism of meiotic recombination is that such understanding is crucial for solving the problem of the adaptive function of sex, a major unresolved issue in biology.
A recent model that reflects current understanding was presented by Anderson and Sekelsky,  and is outlined in the genetic recombination biology figure in this article. The figure shows that two of the four chromatids present early in meiosis prophase I are paired with each other and able to interact.
Recombination, in this version of the model, is initiated by a double-strand break or gap shown in the DNA molecule chromatid at the top of the first figure in this article. However, other types of DNA damage may also initiate recombination. For instance, an genetic recombination biology cross-link caused by genetic recombination biology to a cross-linking agent such as mitomycin C can be repaired by HRR. As indicated in the first figure, above, two types of recombinant product are produced.
This pathway is labeled in the figure as the DHJ double-Holliday junction pathway. Thus, explanations for the adaptive function of meiosis that focus exclusively on crossing-over are inadequate genetic recombination biology explain the majority of recombination events.
Achiasmy is the phenomenon where autosomal recombination is completely absent in one sex of a species. Achiasmatic chromosomal segregation is well documented in male Drosophila melanogaster. Heterochiasmy is the term used to describe recombination rates which differ between the sexes of a species.
In mammals, females most often have higher rates of recombination. The "Haldane-Huxley rule" states that genetic recombination biology usually occurs in the heterogametic sex. From Wikipedia, the free encyclopedia.
Glossary of genetics and cytogenetics: Heidelberg - New York: Genetic recombination biology Biology of the Cell, Fourth Edition. Retrieved February 23, Kendrew John, Lawrence Eleanor eds. The Encyclopedia of Molecular Biology. Chapter 19 in DNA Repair. Transfection Chromosomal crossover Gene conversion Fusion gene Horizontal gene transfer Sister chromatid exchange Transposon. Molecular and cellular biology portal. Retrieved from " https: Cellular processes Molecular genetics.