Recombination Collection

Evolution of the Universe, artwork
Evolution of the Universe. Computer artwork showing the evolution of the Universe from the Big Bang (far left) 12-15 billion years ago to the present day (far right)

E. coli Holliday junction complex C014 / 0878
E. coli Holliday junction complex. Molecular model of a RuvA protein (dark pink) in complex with a Holliday junction between homologous strands of DNA (deoxyribonucleic acid)

DNA 6-way junction, artwork C014 / 2587
DNA 6-way junction. Computer artwork of a synthetic assemblage of nucleic acids which are useful in the design of nanostructures

Bacteriophage DNA recombination F006 / 9554
Bacteriophage DNA recombination. Molecular model showing DNA manipulation and recombination taking place at a Holliday junction with a bacteriophage enzyme

Enzyme catalysing DNA recombination F006 / 9395
Enzyme catalysing DNA recombination. Molecular model of the enzyme CRE (cyclization recombination) recombinase (green and purple) mediating the recombination of strands of DNA (deoxyribonucleic acid)

DNA Holliday junction complex F006 / 9334
DNA Holliday junction complex. Molecular model of the enzyme FLP recombinase in complex with a Holliday junction between homologous strands of DNA (deoxyribonucleic acid)

DNA Holliday junction, molecular model F006 / 9285
DNA Holliday junction. Molecular model of a Holliday junction (centre) between homologous strands of DNA (deoxyribonucleic acid)

E coli Holliday junction complex F006 / 9261
E. coli Holliday junction complex. Molecular model of a RuvA protein (red) in complex with a Holliday junction between homologous strands of DNA (deoxyribonucleic acid, blue) from an E

DNA 6-way junction, artwork C014 / 2586
DNA 6-way junction. Computer artwork of a synthetic assemblage of nucleic acids which are useful in the design of nanostructures

E. coli Holliday junction complex. Molecular model of a RuvA protein (red) in complex with a Holliday junction between homologous strands of DNA (deoxyribonucleic acid, brown and orange) from an E

DNA 6-way junction, artwork C014 / 2588
DNA 6-way junction. Computer artwork of a synthetic assemblage of nucleic acids which are useful in the design of nanostructures. The background depicts a space star nebula

DNA Holliday junction, molecular model C014 / 3090
DNA Holliday junction. Molecular model of a Holliday junction (centre) between homologous strands of DNA (deoxyribonucleic acid)

Enzyme catalysing DNA recombination C016 / 0725
Enzyme catalysing DNA recombination. Molecular model of the enzyme CRE (cyclization recombination) recombinase (blue and green) mediating the recombination of strands of DNA (deoxyribonucleic acid)

Enzyme catalysing DNA recombination C016 / 0724
Enzyme catalysing DNA recombination. Molecular model of the enzyme CRE (cyclization recombination) recombinase (blue and purple) mediating the recombination of strands of DNA (deoxyribonucleic acid)

Resolvase enzyme complexed with DNA, molecular model. The area at centre is a gamma-delta resolvase enzyme forming a complex with two cleaved helices of DNA (deoxyribonucleic acid)

Breast cancer protein and cancer cell C016 / 4613
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer protein and cancer cell C016 / 4612
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer protein and cancer cell C016 / 4610
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer protein and cancer cell C016 / 4608
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer and cancer protein molecule C016 / 4604
Breast cancer. Wireframe computer artwork of a woman with breast cancer. There is a malignant (cancerous) tumour (pink) in the patients right breast

Breast cancer protein and cancer cell C016 / 4600
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer protein and cancer cell C016 / 4598
Artwork showing a molecular model of breast cancer type 1 susceptibility (BRCA1) protein (left) and a cancer cell (right)

Breast cancer protein molecule C016 / 4455
Breast cancer protein. Molecular model of breast cancer type 1 susceptibility (BRCA1) protein. This protein is found in breast and other tissue

Breast cancer protein molecule C016 / 4454
Breast cancer protein. Molecular model of breast cancer type 1 susceptibility (BRCA1) protein. This protein is found in breast and other tissue

Breast cancer protein molecule C016 / 4453
Breast cancer protein. Molecular model of breast cancer type 1 susceptibility (BRCA1) protein. This protein is found in breast and other tissue

Breast cancer protein molecule C016 / 4450
Breast cancer protein. Molecular model of breast cancer type 1 susceptibility (BRCA1) protein. This protein is found in breast and other tissue

DNA Holliday junction complex C013 / 8888
DNA Holliday junction complex. Molecular model of the enzyme FLP recombinase in complex with a Holliday junction between homologous strands of DNA (deoxyribonucleic acid)

Enzyme catalysing DNA recombination C013 / 7915
Enzyme catalysing DNA recombination. Computer model showing the molecular structure of the enzyme CRE (cyclization recombination) recombinase (orange and blue)

Recombinant DNA. Illustration of the DNA molecule (Deoxyribonucleic Acid, showing a recombined fragment. DNA carries the inherited instructions of a living organism)

DNA recombination, molecular model
DNA recombination. Molecular model of a Holliday Junction, a moving point of contact between two DNA (deoxyribonucleic acid)

DNA Holliday junction. Computer model of a Holliday junction (centre) between homologous strands of DNA (deoxyribonucleic acid)

Enzyme catalysing DNA recombination. Computer model of the enzyme flippase recombinase (FLP recombinase, atoms represented as tubes)

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"Recombination: Unveiling the Evolutionary Artwork of the Universe" In the vast expanse of the universe, evolution takes on many forms. One such phenomenon is recombination, a captivating process that shapes and transforms our world. Like an artist's brushstroke on a cosmic canvas, recombination weaves together various elements to create something entirely new. Just as dispersion and total internal reflection give birth to a mesmerizing rainbow, recombination brings forth novel combinations in nature. Figuring prominently in this intricate dance are structures like the E. Coli Holliday junction complex C014 / 0878 and DNA 6-way junctions depicted in stunning artwork C014 / 2587. These molecular masterpieces showcase how genetic material intertwines and rearranges itself with precision. Bacteriophage DNA recombination F006 / 9554 serves as another testament to nature's ingenuity. This process allows for the exchange of genetic information between different viral strains, leading to enhanced adaptability and survival strategies. Enzymes play a crucial role in catalyzing DNA recombination, acting as catalysts that facilitate these transformative processes. Their presence can be seen through striking visuals such as enzyme catalysing DNA recombination F006 / 9395 or within the intricate structure of DNA Holliday junction complexes like F006 / 9334 or F006 / 9261. The complexity deepens further with artwork showcasing DNA's six-way junctions (C014/2586), revealing yet another layer of intricacy within this evolutionary tapestry. Through these glimpses into the world of recombination, we gain insight into nature's ability to innovate and adapt over time, and is through this delicate interplay between molecules that life finds its way forward – constantly evolving towards greater diversity and resilience. So let us marvel at these snapshots from nature's gallery – where artistry meets science – reminding us that even amidst chaos, there is beauty in the recombination of life's building blocks.