Fluorescent Protein Production, Purification, and Coupling to Microspheres.

Fluorescent proteins (FPs) have become an essential tool for biological research. Since the isolation and description of green FP, hundreds of FPs have been discovered and created with various characteristics. The excitation of these proteins ranges from ultraviolet (UV) up to near infrared (NIR).

BAK/BAX macropores facilitate mitochondrial herniation and mtDNA efflux during apoptosis.

Mitochondrial apoptosis is mediated by BAK and BAX, two proteins that induce mitochondrial outer membrane permeabilization, leading to cytochrome c release and activation of apoptotic caspases. In the absence of active caspases, mitochondrial DNA (mtDNA) triggers the innate immune cGAS/STING pathway, causing dying cells to secrete type I interferon. How cGAS gains access to mtDNA remains unclear.

The N-terminal domain of MuB protein has striking structural similarity to DNA-binding domains and mediates MuB filament-filament interactions.

MuB is an ATP-dependent DNA-binding protein that regulates the activity of MuA transposase and delivers the target DNA for transposition of phage Mu. Mechanistic insight into MuB function is limited to its AAA+ ATPase module, which upon ATP binding assembles into helical filaments around the DNA. However, the structure and function of the flexible N-terminal domain (NTD) appended to the AAA+ module remains uncharacterized.

MuB gives a new twist to target DNA selection.

Transposition target immunity is a phenomenon observed in some DNA transposons that are able to distinguish the host chromosome from their own DNA sequence, thus avoiding self-destructive insertions. The first molecular insight into target selection and immunity mechanisms came from the study of phage Mu transposition, which uses the protein MuB as a barrier to self-insertion. MuB is an ATP-dependent non-specific DNA binding protein that regulates the activity of the MuA transposase and captures target DNA for transposition.

MuB is an AAA+ ATPase that forms helical filaments to control target selection for DNA transposition.

MuB is an ATP-dependent nonspecific DNA-binding protein that regulates the activity of the MuA transposase and captures target DNA for transposition. Mechanistic understanding of MuB function has previously been hindered by MuB's poor solubility. Here we combine bioinformatic, mutagenic, biochemical, and electron microscopic analyses to unmask the structure and function of MuB.