Addgene Stands with the Scientific Community

By Chonnettia Jones

Recent Posts

Antibodies 101: Normalization and Loading Controls for Western Blots

Emily P. Bentley April 8, 2025

Ah, the notorious western blot: we meet again. So useful, yet so finicky to design and optimize. Today we’ll cover the normalization and loading controls needed for relative quantification of a western blot — and why you might want to be careful relying on so called ...

A smiling Blugene holding a cartoon western blot.

CRISPR 101

CRISPR 101: Any Base Transversion Editors

Emily P. Bentley April 1, 2025

In our last post, we talked about the first base transversion editors: CGBEs, or C → G Base Editors. CGBEs first convert a cytosine (C) to uracil (U), just like Cytosine Base Editors (CBEs). But unlike CBEs, CGBEs then excise the U to create an abasic (empty) DNA site using ...

The nucleobases are shown with arrows describing conversions between them. In step one, an adenosine deaminase converts adenine to hypoxanthine (the nucleobase component of inosine); this is catalyzed directly by the base editor. Next, base excision of hypoxanthine (also by the base editor) could be repaired in two different ways by the cell, shown by an arrow that splits into two outcomes. The repair pathway leading to cytosine is favored by ACBEs, while the repair pathway leading to thymine is favored by AYBEv3 + Polη.

CRISPR 101

CRISPR 101: Cytosine Transversion Editors

Emily P. Bentley March 25, 2025

The first base editors revolutionized CRISPR gene editing. Cytosine base editors (CBEs) and adenine base editors (ABEs) chemically modify target bases without breaking the DNA backbone, making them efficient and precise tools for altering DNA sequences. These first base editors ...

The nucleobases are shown with arrows describing conversions between them. In step one, a cytosine deaminase converts cytosine to uracil; this is catalyzed directly by the base editor. Next, base excision of uracil (also by the base editor) is repaired in two different ways by the cell, shown by an arrow that splits into two outcomes. Repair in E. coli leads to adenine, while repair in mammalian cells leads to guanine.

CRISPR

Typing CRISPR Systems

Alyssa Shepard March 18, 2025

What’s in a type? That which we call CRISPR, by any other name would…probably still edit genomes.

A schematic overview of the CRISPR classification system.

Hot Plasmids

Hot Plasmids: Winter 2025

Multiple Authors March 11, 2025

Every few months, we highlight some of the new plasmids, antibodies, and viral preps in the repository through our Hot Plasmids articles.

Reflections and Looking Ahead

Chonnettia Jones February 25, 2025

Twenty years of accelerating scientific discovery. Over 150,000 plasmids empowering researchers worldwide. Countless breakthroughs enabled by shared resources. As we step into 2025, these milestones remind us of the extraordinary impact that happens when scientists come together ...

CRISPR

CRISPR 101: Cytosine and Adenine Base Editors

Multiple Authors February 13, 2025

Early CRISPR applications were often limited by the low editing efficiency of homology-directed repair (HDR), the pathway for resolving DNA double-strand breaks (DSBs) preferred by researchers. Compared to non-homologous end joining (NHEJ), HDR occurs at a relatively low ...

A cartoon depiction of cytidine base editing. A base editor, consisting of a cytidine deaminase fused to Cas9, is shown binding to DNA using its guide RNA. The guide RNA base pairs to target DNA, leaving the opposite strand of DNA free to be contacted by the cytidine deaminase, which converts a C to a U within this single-stranded sequence. This deamination yields DNA with a G:U mismatch without creating a double-strand break. Mismatch repair preserves the edit IF the modified strand is used as the template, converting the mismatched G to an A and yielding a single-base-pair edit.