Genetics Collection (page 9)

Bullets

DNA autoradiogram F005 / 7308
DNA autoradiogram

TATA box-binding protein complex C014 / 0867
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, khaki) complexed with a strand of DNA (deoxyribonucleic acid)

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)

Genetic research, conceptual image C014 / 1256
Genetic research. Conceptual image of a molecular model of a strand of DNA (deoxyribonucleic acid) being held on a human hand

Synthetic DNA molecule
Synthetic DNA. Molecule model of a synthetic form of DNA (deoxyribonucleic acid). DNA is composed of two strands twisted into a double helix

DNA supercoil, artwork
DNA supercoils. Computer artwork showing a supercoiled strand of DNA (deoxyribonucleic acid). Supercoiling is important in a number of biological processes

Tyrosyl-tRNA synthetase molecule
Tyrosyl-tRNA synthetase protein molecule. Molecular model showing bacterial tyrosyl-tRNA synthetase complexed with tyrosyl tRNA (transfer ribonucleic acid)

Endonuclease IV molecule. Molecular model of the endonuclease IV restriction enzyme EcoRV (grey) bound to a cleaved section of DNA (deoxyribonucleic acid, blue, orange and pink)

Tumour suppressor protein and DNA C017 / 3645
Tumour suppressor protein and DNA. Computer artwork showing a molecule of the tumour suppressor protein p53 (blue and pink) bound to a molecule of DNA (deoxyribonucleic acid, yellow and orange)

Synthetic biology, conceptual artwork C018 / 0907
Synthetic biology, conceptual illustration. Lab set-up inside a yeast cell

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

Tryptophanyl-tRNA synthetase molecule
Tryptophanyl-tRNA synthetase protein molecule. Molecular model showing human tryptophanyl-tRNA synthetase complexed with tryptophan tRNA (transfer ribonucleic acid)

Genetics research, conceptual artwork C017 / 7412
Genetics research. conceptual computer artwork

HeLa cell, SEM C014 / 0371
HeLa cell. Coloured scanning electron micrograph (SEM) of a HeLa cell (centre) grown in a 3D matrix (background). HeLa cells are a continuously cultured cell line of immortal human cancer cells

Pho4 transcription factor bound to DNA C014 / 0861
Pho4 transcription factor bound to DNA. Molecular model showing phosphate system positive regulatory protein (Pho4) (blue and green) bound to a strand of DNA (deoxyribonucleic acid, red and purple)

Meiosis, artwork F006 / 2399
Meiosis. Computer artwork of the first meiotic division

Genetics research, conceptual artwork C017 / 7407
Genetics research. conceptual computer artwork

Meiosis, artwork F006 / 2252
Meiosis. Computer artwork of the first meiotic division

Genetics research, conceptual artwork C017 / 7409
Genetics research. conceptual computer artwork

EcoRV restriction enzyme molecule C014 / 2117
EcoRV restriction enzyme. Molecular model of the type II restriction enzyme EcoRV (purple and blue) bound to a DNA molecule (deoxyribonucleic acid, pink and white)

Gene expression, artwork
Gene expression. Computer artwork showing the process of transcription, the first stage or gene expression. Here, a chromosome (distance)

DNA molecule, artwork F007 / 1996
DNA molecule, computer artwork

DNA molecule, artwork F007 / 1994
DNA molecule, computer artwork

DNA molecule, artwork F007 / 1995
DNA molecule, computer artwork

DNA molecule, artwork F007 / 1991
DNA molecule, computer artwork

DNA molecule, artwork F007 / 1992
DNA molecule, computer artwork

EcoRV restriction enzyme molecule C014 / 2112
EcoRV restriction enzyme. Molecular model of the type II restriction enzyme EcoRV (pink) bound to a cleaved section of DNA (deoxyribonucleic acid, yellow)

TATA box-binding protein complex C017 / 7090
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, green) complexed with a strand of DNA (deoxyribonucleic acid, spheres) and transcription factor IIB

TATA box-binding protein complex C017 / 7085
TATA box-binding protein complex. Molecular model showing a TATA box-binding protein (TBP, green) complexed with a strand of DNA (deoxyribonucleic acid, yellow) and transcription factor IIB

Adenine molecule, artwork C017 / 7199
Adenine molecule. Computer artwork showing the structure of a molecule of the nucleobase adenine. Atoms are colour-coded spheres: carbon (green), nitrogen (blue), and oxygen (white)

Junk DNA, conceptual image. Computer artwork of damaged DNA (deoxyribonucleic acid) in a rubbish bin. DNA contains sections called genes that encode the bodys genetic information

DNA repair, artwork
DNA repair. Computer artwork of a DNA (deoxyribonucleic acid) ligase enzyme (yellow) repairing damaged DNA (spiral) in a chromosome (upper left)

EcoRV restriction enzyme molecule C014 / 2114
EcoRV restriction enzyme. Molecular model of the type II restriction enzyme EcoRV (white and gold) bound to a cleaved section of DNA (deoxyribonucleic acid, orange and yellow)

Genetics research F007 / 0348
Genetics research

Genetic analysis F007 / 0342
Genetic analysis

Genetic analysis F007 / 0343
Genetic analysis

Gel electrophoresis F007 / 0320
Gel electrophoresis chamber

Genetic code, artwork F006 / 8998
Genetic code, computer artwork

EcoRV restriction enzyme molecule C014 / 2116
EcoRV restriction enzyme. Molecular model of the type II restriction enzyme EcoRV (purple and blue) bound to a DNA molecule (deoxyribonucleic acid, pink and white)

Genetic code, artwork F006 / 8997
Genetic code, computer artwork

Creation of artificial life, artwork F006 / 8968
Creation of artificial life, conceptual computer artwork

DNA molecule, artwork F006 / 8969
DNA molecule, computer artwork

Creation of artificial life, artwork F006 / 8967
Creation of artificial life, conceptual computer artwork

Designer babies, conceptual artwork F006 / 8957
Designer babies, conceptual computer artwork

Chickenosaurus, artwork C017 / 0692
Chickenosaurus. Artwork of a chicken with teeth. Chickens are descended from dinosaurs and it may be possible to reverse evolution to give modern-day chickens dinosaur-like features

Genetic evolution of flu virus, artwork C017 / 0786
Genetic evolution of influenza (flu) virus. Artwork showing how reassortment of the influenza virus genome led to the evolution of the H7N9 virus in China

DNA molecules, artwork F007 / 0044
DNA molecules, computer artwork

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"Unlocking the Secrets of Life: Exploring the Fascinating World of Genetics" From the intricate DNA molecule to the X and Y chromosomes, a captivating field that unravels the blueprint of life. As we peer into a computer screen displaying a human genetic sequence, we witness the complexity encoded within our very cells. The double-stranded RNA molecule serves as a messenger, carrying vital information for DNA transcription. Molecular models illustrate how this process shapes our traits and characteristics. It was through their groundbreaking work that Watson and Crick discovered the structure of DNA, forever changing our understanding of genetics. Richard Dawkins, an esteemed British science writer, has played an influential role in popularizing genetics among masses. His insightful writings have shed light on evolutionary biology and its connection to our genetic makeup. Intriguingly captured by scanning electron microscopy (SEM), an embryonic stem cell alongside a needle reminds us of the immense potential held within these tiny building blocks. Mitosis comes alive under a light micrograph, showcasing how cells divide and multiply with precision. Computer artwork depicting beta DNA segments interlaced with spheres hints at ongoing research pushing boundaries in genetic engineering. The nucleotide base matrix acts as a foundation for decoding genetic information - each letter representing crucial instructions embedded within our genes. Genetics holds endless possibilities - from unraveling hereditary diseases to designing personalized medicine based on individual genomes. With every discovery made in this ever-evolving field, humanity inches closer towards harnessing nature's codebook for better health and understanding ourselves more deeply than ever before.