Andrew Min scite author profile

Understanding the energetics of molecular interactions is fundamental to all of the central quests of structural biology including structure prediction and design, mapping evolutionary pathways, learning how mutations cause disease, drug design, and relating structure to function. Hydrogen-bonding is widely regarded as an important force in a membrane environment because of the low dielectric constant of membranes and a lack of competition from water. Indeed, polar residue substitutions are the most common disease-causing mutations in membrane proteins. Because of limited structural information and technical challenges, however, there have been few quantitative tests of hydrogen-bond strength in the context of large membrane proteins. Here we show, by using a double-mutant cycle analysis, that the average contribution of eight interhelical side-chain hydrogen-bonding interactions throughout bacteriorhodopsin is only 0.6 kcal mol(-1). In agreement with these experiments, we find that 4% of polar atoms in the non-polar core regions of membrane proteins have no hydrogen-bond partner and the lengths of buried hydrogen bonds in soluble proteins and membrane protein transmembrane regions are statistically identical. Our results indicate that most hydrogen-bond interactions in membrane proteins are only modestly stabilizing. Weak hydrogen-bonding should be reflected in considerations of membrane protein folding, dynamics, design, evolution and function.

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The crystal structure of the Rv0301‐Rv0300 VapBC‐3 toxin—antitoxin complex from M. tuberculosis reveals a Mg²⁺ ion in the active site and a putative RNA‐binding site

Min

Miallau

Sawaya

et al. 2012

Protein Science

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VapBC pairs account for 45 out of 88 identified toxin-antitoxin (TA) pairs in the Mycobacterium tuberculosis (Mtb) H37Rv genome. A working model suggests that under times of stress, antitoxin molecules are degraded, releasing the toxins to slow the metabolism of the cell, which in the case of VapC toxins is via their RNase activity. Otherwise the TA pairs remain bound to their promoters, autoinhibiting transcription. The crystal structure of Rv0301-Rv0300, an Mtb VapBC TA complex determined at 1.49 Å resolution, suggests a mechanism for these three functions: RNase activity, its inhibition by antitoxin, and its ability to bind promoter DNA. The Rv0301 toxin consists of a core of five parallel beta strands flanked by alpha helices. Three proximal aspartates coordinate a Mg 21 ion forming the putative RNase active site. The Rv0300 antitoxin monomer is extended in structure, consisting of an N-terminal beta strand followed by four helices. The last two helices wrap around the toxin and terminate near the putative RNase active site, but with different conformations. In one conformation, the C-terminal arginine interferes with Mg 21 ion coordination, suggesting a mechanism by which the antitoxin can inhibit toxin activity. At the N-terminus of the antitoxin, two pairs of Ribbon-Helix-Helix (RHH) motifs are related by crystallographic twofold symmetry. The resulting hetero-octameric complex is similar to the FitAB system, but the two RHH motifs are about 30 Å closer together in the Rv0301-Rv0300 complex, suggesting either a different span of the DNA recognition sequence or a conformational change.

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Forces that stabilize membrane proteins

Joh

Yang

Min

et al. 2009

Biophysical Journal

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Rv0301 Rv0300 Toxin Antitoxin Complex from Mycobacterium tuberculosis

Min¹,

Sawaya²,

Cascio³

et al. 2009

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Andrew Min

Modest stabilization by most hydrogen-bonded side-chain interactions in membrane proteins

The crystal structure of the Rv0301‐Rv0300 VapBC‐3 toxin—antitoxin complex from M. tuberculosis reveals a Mg²⁺ ion in the active site and a putative RNA‐binding site

Forces that stabilize membrane proteins

Rv0301 Rv0300 Toxin Antitoxin Complex from Mycobacterium tuberculosis

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Andrew Min

Modest stabilization by most hydrogen-bonded side-chain interactions in membrane proteins

The crystal structure of the Rv0301‐Rv0300 VapBC‐3 toxin—antitoxin complex from M. tuberculosis reveals a Mg2+ ion in the active site and a putative RNA‐binding site

Forces that stabilize membrane proteins

Rv0301 Rv0300 Toxin Antitoxin Complex from Mycobacterium tuberculosis

Contact Info

Product

Resources

About

The crystal structure of the Rv0301‐Rv0300 VapBC‐3 toxin—antitoxin complex from M. tuberculosis reveals a Mg²⁺ ion in the active site and a putative RNA‐binding site