The effect of amino acid deletions and substitutions in the longest loop of GFP

<p>Abstract</p> <p>Background</p> <p>The effect of single and multiple amino acid substitutions in the green fluorescent protein (GFP) from <it>Aequorea victoria </it>has been extensively explored, yielding several proteins of diverse spectral properties. However, the role of amino acid deletions in this protein -as with most proteins- is still unknown, due to the technical difficulties involved in generating combinatorial in-phase amino acid deletions on a target region.</p> <p>Results</p> <p>In this study, the region I129-L142 of superglo GFP (sgGFP), corresponding to the longest loop of the protein and located far away from the central chromophore, was subjected to a random amino acid deletion approach, employing an in-house recently developed mutagenesis method termed Codon-Based Random Deletion (COBARDE). Only two mutants out of 16384 possible variant proteins retained fluorescence: sgGFP-Δ I129 and sgGFP-Δ D130. Interestingly, both mutants were thermosensitive and at 30°C sgGFP-Δ D130 was more fluorescent than the parent protein. In contrast with deletions, substitutions of single amino acids from residues F131 to L142 were well tolerated. The substitution analysis revealed a particular importance of residues F131, G135, I137, L138, H140 and L142 for the stability of the protein.</p> <p>Conclusion</p> <p>The behavior of GFP variants with both amino acid deletions and substitutions demonstrate that this loop is playing an important structural role in GFP folding. Some of the amino acids which tolerated any substitution but no deletion are simply acting as "spacers" to localize important residues in the protein structure.</p

Evolution of substrate specificity in a recipient's enzyme following horizontal gene transfer

Despite the prominent role of horizontal gene transfer (HGT) in shaping bacterial metabolism, little is known about the impact of HGT on the evolution of enzyme function. Specifically, what is the influence of a recently acquired gene on the function of an existing gene? For example, certain members of the genus Corynebacterium have horizontally acquired a whole L-tryptophan biosynthetic operon, whereas in certain closely related actinobacteria, for example, Mycobacterium, the trpF gene is missing. In Mycobacterium, the function of the trpF gene is performed by a dual-substrate (βα)8 phosphoribosyl isomerase (priA gene) also involved in L-histidine (hisA gene) biosynthesis. We investigated the effect of a HGT-acquired TrpF enzyme upon PriA’s substrate specificity in Corynebacterium through comparative genomics and phylogenetic reconstructions. After comprehensive in vivo and enzyme kinetic analyses of selected PriA homologs, a novel (βα)8 isomerase subfamily with a specialized function in L-histidine biosynthesis, termed subHisA, was confirmed. X-ray crystallography was used to reveal active-site mutations in subHisA important for narrowing of substrate specificity, which when mutated to the naturally occurring amino acid in PriA led to gain of function. Moreover, in silico molecular dynamic analyses demonstrated that the narrowing of substrate specificity of subHisA is concomitant with loss of ancestral protein conformational states. Our results show the importance of HGT in shaping enzyme evolution and metabolism

SWISS-MODEL es un generador de modelos estructurales de proteínas cuyas estructuras aún no están depositadas en el PDB

En los últimos 15 años, los científicos han mejorado la habilidad para generar modelos estructurales de las proteínas, cuya estructura tridimensional (3D) se desconoce, gracias al crecimiento del número de estructuras depositadas en la base de datos Protein Data Bank (PDB). En la actualidad, uno de los métodos más usados y más rápidos para la generación de modelos estructurales es el servidor bioinformático SWISS-MODEL, creado para el modelado por homología de estructuras 3D, que comparten hasta 30% de identidad en su secuencia de aminoácidos con otras proteínas de estructura conocida. La calidad de los modelos resultantes se evalúa con varios parámetros bioquímicos (por ejemplo: QMEAN, RAMACHANDRAN plot). El modelo puede mejorarse al incluir el SWISS-MODEL en una línea de trabajo, seguido del servidor CHARMM-GUI y el programa GROMACS. Mientras el servidor CHARMM-GUI aplica al modelo producido, parámetros de un campo de fuerza para crear un sistema proteína-agua, bajo condiciones relevantes biológicamente, apto para simulación, el programa GROMACS minimiza la energía del modelo hasta alcanzar una estructura energéticamente estable, más cercana a como se encuentra en solución o en el sistema biológico. Los modelos generados por esta línea de trabajo pueden ser analizados a detalle por los biólogos estructurales en programas para visualización, como PyMOL, para obtener un mayor entendimiento del fenómeno biológico bajo estudio

TrimerDimer: an oligonucleotide-based saturation mutagenesis approach that removes redundant and stop codons

9-fluorenylmethoxycarbonyl (Fmoc) and 4,4′-dimethoxytrityl (DMTr) are orthogonal hydroxyl protecting groups that have been used in conjunction to assemble oligonucleotide libraries whose variants contain wild-type and mutant codons randomly interspersed throughout a focused DNA region. Fmoc is labile to organic bases and stable to weak acids, whereas DMTr behaves oppositely. Based on these chemical characteristics, we have now devised TrimerDimer, a novel codon-based saturation mutagenesis approach that removes redundant and stop codons during the assembly of degenerate oligonucleotides. In this approach, five DMTr-protected trinucleotide phosphoramidites (dTGG, dATG, dTTT, dTAT and dTGC) and five Fmoc-protected dinucleotide phosphoramidites (dAA, dTT, dAT, dGC and dCG) react simultaneously with a starting oligonucleotide growing on a solid support. The Fmoc group is then removed and the incorporated dimers react with a mixture of three DMTr-protected monomer phosphoramidites (dC, dA and dG) to produce 15 trinucleotides: dCAA, dAAA, dGAA, dCTT, dATT, dGTT, dCAT, dAAT, dGAT, dCGC, dAGC, dGGC, dCCG, dACG and dGCG. After one mutagenic cycle, 20 codons are generated encoding the 20 natural amino acids. TrimerDimer was tested by randomizing the four contiguous codons that encode amino acids L64–G67 of an engineered, nonfluorescent GFP protein. Sequencing of 89 nonfluorescent mutant clones and isolation of two fluorescent mutants confirmed the principle

Protein evolution by codon-based random deletions

A method to delete in-phase codons throughout a defined target region of a gene has been developed. This approach, named the codon-based random deletion (COBARDE) method, is able to delete complete codons in a random and combinatorial mode. Robustness, automation and fine-tuning of the mutagenesis rate are essential characteristics of the method, which is based on the assembly of oligonucleotides and on the use of two transient orthogonal protecting groups during the chemical synthesis. The performance of the method for protein function evolution was demonstrated by changing the substrate specificity of TEM-1 β-lactamase. Functional ceftazidime-resistant β-lactamase variants containing several deleted residues inside the catalytically important omega-loop region were found. The results show that the COBARDE method is a useful new molecular tool to access previously unexplorable sequence space