Journal:Proteins:2

Protein Stability and in Vivo Concentration of Missense Mutations in Phenylalanine Hydroxylase

Zhen Shi, Jenn Sellers, and John Moult ^[1]

Molecular Tour
A previous computational analysis of missense mutations linked to monogenic disease found a high proportion of missense mutations affect protein stability, rather than other aspects of protein structure and function. The purpose of the present study is to relate the presence of such stability damaging missense mutations to the levels of a particular protein present under in vivo like conditions, and to test the reliability of the computational methods. Experimental data on a set of missense mutations of the enzyme phenylalanine hydroxylase (PAH) associated with the monogenic disease phenylketonuria (PKU) have been compared with the expected in vivo impact on protein function, obtained using SNPs3D, an in silico analysis package. A high proportion of the PAH mutations are predicted to be destabilizing. The overall agreement between predicted stability impact and experimental evidence for lower protein levels is in accordance with the estimated error rates of the methods. For these mutations, destabilization of protein three dimensional structure is the major molecular mechanism leading to PKU, and results in a substantial reduction of in vivo PAH protein concentration. Although of limited scale, the results support the view that destabilization is the most common mechanism by which missense mutations cause monogenic disease. In turn, this conclusion suggests the general therapeutic strategy of developing drugs targeted at restoring wild type stability.

Under physiological conditions, , with each subunit composed of three domains. From N terminal to C terminal these are the regulatory, catalytic and tetramerization domains. To date, no experimentally determined structure of the complete human molecule is available. Three PDB structures were selected to model specific mutations in different domains based on crystal structure resolution, structure quality, and coverage: 1j8u, (monomeric form); 2pah, (tetrameric complex); and 1phz, (dimeric complex). The high resolution human 1j8u structure was used to model catalytic domain mutations. Regulatory domain mutations were modeled using a homology model of the human domain, based on the rat 1phz structure, as were three catalytic domain mutations, R261Q, R413P, and Y414C, that are in contact with the regulatory domain across a subunit interface. Rat PAH protein has 93% sequence identity with human PAH. There are no insertions or deletions in sequence between the two proteins. Main chain coordinates were taken directly from the rat structure. Side chains conformations were optimized using SCRWL. Catalytic domain mutations R408W and R408Q are in contact with the tetramerization domain of another subunit and were modeled using 2pah.

. Domains are: regulatory (yellow); catalytic (green); tetramerization (blue). The Fe (++) ion and cofactor Tetrahydrobiopterin (BH4) are shown space filled. The substrate L-Phe and cofactor tetrahydrobiopterin (BH4) both have binding sites in the catalytic domain.

Category 1: 28 missense mutations are expected to affect stability only

28 of the 35 mutations with destabilization assignments are remote from any known ligand binding or the catalytic site, and so are expected to have a low experimental protein level, and wild type specific activity.

, in orangered) have protein levels less than 50% wild type, as expected. Of these, all but two have wild type specific activity. The two exceptions, , have approximately three fold higher specific activities than the wild type. These mutations lie in the regulatory domain, suggesting a possible explanation for the high activity level. The 16 mutants are classified into clinical categories of mild PKU , moderate PKU , and classic PKU .

Nine of remaining mutations expected to affect stability only , in red) have reported experimental protein levels greater than 50% of wild type (all 100%, except one of the R408Q experiments with 70%), inconsistent with the computational assignment.

Category 2: Seven missense mutations are expected to affect both stability and molecular function

There are seven mutations , in magenta) with atomic contacts of 6.5 Å or less to the phenylalanine substrate, the BH4 cofactor or the Fe++ ion, and that are assigned as destabilizing by the structure SVM. These mutant proteins are therefore expected to exhibit a combination of lower specific activity and a lower total protein level. Six of the seven (G247V, L255S, R270S, E280K, S349L, S349P) have protein levels less than half or in one case close to half (G247V, 56%) that of wild type, and very low protein activity, consistent with expectations. Clinical categories are available for E280K, S349L, and S349P, and are all “classic PKU”, consistent with the results and with

experiment. The remaining mutant in this category, Y277D, has an experimental activity of zero, and is classified as mild or classic PKU, consistent with the profile SVM assignments. But the measured protein level is reported as 99% of wild type, inconsistent with a modest confidence stability assignment. This may be a computational false positive with respect to stability.