Malaria drug resistance is associated with defective DNA mismatch repair.

Malarial parasites exhibit striking genetic plasticity, a hallmark of which is an ever-increasing rate of resistance to new drugs, especially in Southeast Asia where multi-drug resistance (MDR) threatens the last line of antimalarial drugs, the artesunate compounds. Previous studies quantified the accelerated resistance to multiple drugs (ARMD) phenomenon, but the underpinning mechanism(s) remains unknown. We utilize a forward genetic assay to investigate a new hypothesis that defective DNA mismatch repair (MMR) contributes to the development of MDR by Plasmodium falciparum parasites.

Chromosomal proteins HMGN3a and HMGN3b regulate the expression of glycine transporter 1.

HMGN proteins promote chromatin unfolding, enhance access to nucleosomes, and modulate transcription from chromatin templates. It is not known whether they act indiscriminately as general modulators of transcription or whether they regulate specific gene expression. Here, we investigated the role of HMGN3, a recently discovered HMGN family member, in transcription in vivo.

Protein expression patterns for ubiquitous and tissue specific calpains in the developing mouse lens.

Calcium activated proteases (calpains) have been implicated in the processing of lens crystallins during lens maturation and cataract formation. Ubiquitous type calpain 2 and calpain 10 and lens specific Lp82 and Lp85 protein distribution were determined using immunohistochemistry and immunoblotting in embryonic and post-natal mouse eyes. Calpain 2 was first expressed late in embryonic development and localized to the lens epithelium and transition zone.