 |
Adenine Riboswitch in Action
XFEL serial crystallography reveals what happens when adenine binds to a riboswitch
|
 |
ATM and ATR Kinases
Dividing cells use ATM and ATR kinases to respond to DNA damage.
|
 |
Designed DNA Crystal
Small pieces of DNA have been engineered to form a nanoscale lattice
|
 |
DNA
Atomic structures reveal how the iconic double helix encodes genomic information
|
 |
Fluorescent RNA Aptamers
RNA aptamers are being engineered to track molecules inside living cells
|
 |
Nucleosome
The cell's genome is stored and protected by nucleosomes
|
 |
RecA and Rad51
Broken DNA strands may be repaired by matching sequences in a duplicate copy of the DNA
|
 |
Restriction Enzymes
Bacterial enzymes that cut DNA are useful tools for genetic engineering
|
 |
Ribonuclease P
The ribozyme ribonuclease P cleaves pre-tRNA to form functional tRNA.
|
 |
Ribosomal Subunits
Atomic structures of the ribosomal subunits reveal a central role for RNA in protein synthesis
|
 |
Ribosome
Ribosomes are complex molecular machines that build proteins
|
 |
Riboswitches
Special sequences of messenger RNA can bind to regulatory molecules and affect synthesis of proteins
|
 |
Self-splicing RNA
Special sequences of RNA are able to splice themselves
|
 |
Small Interfering RNA (siRNA)
Our cells continually look for pieces of double-stranded RNA, a possible sign of viral infection
|
 |
Spliceosomes
Cryoelectron microscropy is revealing how spliceosomes cut-and-paste messenger RNA molecules.
|
 |
Telomerase
Telomerase maintains the ends of our chromosomes.
|
 |
Thymine Dimers
Ultraviolet light damages our DNA, but our cells have ways to correct the damage
|
 |
Transfer RNA
Transfer RNA translates the language of the genome into the language of proteins
|
 |
Transfer-Messenger RNA
tmRNA rescues ribosomes that are stalled by damaged messenger RNA
|
 |
Vitamin D Receptor
Vitamin D helps regulate the use of calcium throughout the body
|
|
Adenine Riboswitch in Action
XFEL serial crystallography reveals what happens when adenine binds to a riboswitch
|
|
ATM and ATR Kinases
Dividing cells use ATM and ATR kinases to respond to DNA damage.
|
|
Designed DNA Crystal
Small pieces of DNA have been engineered to form a nanoscale lattice
|
|
DNA
Atomic structures reveal how the iconic double helix encodes genomic information
|
|
Fluorescent RNA Aptamers
RNA aptamers are being engineered to track molecules inside living cells
|
 |
FOXP3
A master transcriptional regulator of immune tolerance
|
|
Nucleosome
The cell's genome is stored and protected by nucleosomes
|
|
RecA and Rad51
Broken DNA strands may be repaired by matching sequences in a duplicate copy of the DNA
|
|
Restriction Enzymes
Bacterial enzymes that cut DNA are useful tools for genetic engineering
|
|
Ribonuclease P
The ribozyme ribonuclease P cleaves pre-tRNA to form functional tRNA.
|
|
Ribosomal Subunits
Atomic structures of the ribosomal subunits reveal a central role for RNA in protein synthesis
|
|
Ribosome
Ribosomes are complex molecular machines that build proteins
|
|
Riboswitches
Special sequences of messenger RNA can bind to regulatory molecules and affect synthesis of proteins
|
|
Self-splicing RNA
Special sequences of RNA are able to splice themselves
|
|
Small Interfering RNA (siRNA)
Our cells continually look for pieces of double-stranded RNA, a possible sign of viral infection
|
|
Spliceosomes
Cryoelectron microscropy is revealing how spliceosomes cut-and-paste messenger RNA molecules.
|
|
Telomerase
Telomerase maintains the ends of our chromosomes.
|
|
Thymine Dimers
Ultraviolet light damages our DNA, but our cells have ways to correct the damage
|
|
Transfer RNA
Transfer RNA translates the language of the genome into the language of proteins
|
|
Transfer-Messenger RNA
tmRNA rescues ribosomes that are stalled by damaged messenger RNA
|
|
Vitamin D Receptor
Vitamin D helps regulate the use of calcium throughout the body
|
