Role of Conserved Salt Bridges in Homeodomain Stability and DNA Binding

Torrado, Mario; Revuelta, Julia; González, Carlos; Corzana, Francisco; Bastida, Ágatha; Asensio, Juan Luis

doi:10.1074/jbc.m109.012054

Cited by 12 publications

(21 citation statements)

References 38 publications

(44 reference statements)

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“…Q186 is located in the middle of helix α3 of the homeodomain structure within the protein-DNA binding interface (Figure 3C). Q186, which corresponds to Q50 in standard homeodomain nomenclature [35], is preserved in all six Dlx proteins and highly conserved in other homeodomains. Only a few residues types can be tolerated in position 50 and, while glutamine is most common, some homeodomain structures contain lysine, serine or cysteine instead [36].…”

Section: Discussionmentioning

confidence: 99%

“…The second mutation linked to SHFM-1 involves residue Q178, which is preserved across all six Dlx homeodomains and is highly conserved within DLX5 genes from different species [23]. Q178 corresponds to Q42 in the standard homeodomain nomenclature, and is positioned too far from the DNA and is typically occupied by a glutamic acid involved in a salt bridge with R167 (R31), which is one of three highly conserved salt bridges that are believed to play a role in stabilizing the homeodomain structure [35]. Mutations of residues in positions 31/42 induce stabilizing or destabilizing effects on the protein.…”

Section: Discussionmentioning

confidence: 99%

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Dlx5 Homeodomain:DNA Complex: Structure, Binding and Effect of Mutations Related to Split Hand and Foot Malformation Syndrome

Proudfoot

Axelrod

Geralt

et al. 2016

Journal of Molecular Biology

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SUMMARY The Dlx5 homeodomain is a transcription factor related to the Drosophila Distal-less gene that is associated with breast and lung cancer, lymphoma, Rett syndrome and osteoporosis in humans. Mutations in the DLX5 gene have been linked to deficiencies in craniofacial and limb development in higher eukaryotes, including Split Hand and Foot Malformation-1 (SHFM-1) in humans. Our characterization of a Dlx5 homeodomain–(CGACTAATTAGTCG)2 complex by NMR spectroscopy paved the way for determination of its crystal structure at 1.85 Å resolution that enabled rationalization of the effects of disease-related mutations on the protein function. A remarkably subtle mutation, Q186H, is linked to SHFM-1; this change likely affects affinity of DNA binding by disrupting water-mediated interactions with the DNA major groove. A more subtle effect is implicated for the Q178P mutation, which is not in direct contact with the DNA. Our data indicate that these mutations diminish the ability of the Dlx5 homeodomain to recognize and bind target DNAs, and likely destabilize the formation of functional complexes.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Dlx5 Homeodomain:DNA Complex: Structure, Binding and Effect of Mutations Related to Split Hand and Foot Malformation Syndrome

Proudfoot

Axelrod

Geralt

et al. 2016

Journal of Molecular Biology

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“…Others have shown for nine different homeodomains that replacement of either Glu17 or Arg52 (residue numbering according to Torrado et al, 2009; in the Gbx1 constructs used in our work, these positions are shifted to Glu23 and Arg58, but to facilitate correlations with other homeodomains we also use the numbering in Torrado et al, 2009; see Fig. 1a) by a neutral amino acid caused decreased protein stability, resulting in protein aggregation during purification (Chi et al, 2005).…”

Section: Resultsmentioning

confidence: 99%

“…The residues Glu17 and Arg52 (residue numbering of Torrado et al, 2009) are highly conserved among homeodomains, and crystal structures (Grant et al, 2000; Jauch et al, 2008; Hovde et al, 2001) and molecular dynamics studies (Flader et al, 2003) of homeodomain–DNA complexes suggested that these two residues form a salt bridge in the free homeodomains which is preserved in their DNA complexes. In apparent contrast, interactions between Arg52 and the DNA backbone had either been directly observed in or inferred by NMR structure determinations of different homeodomain–DNA complexes (Baird-Titus et al, 2006; Billeter et al, 1993; Chaney et al, 2005).…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, several amino acid pairs have been identified that contribute to protein stability through the formation of salt bridges between the different α-helices. The most highly conserved salt bridge in the homeodomain family links Glu17 and Arg52 in helices 1 and 3, and salt bridges between residues Glu19 and Arg30, and between Arg31 and Glu42 are also quite common (Torrado et al, 2009). Comparison of the different individual molecules in the crystallographic asymmetric unit (Longo et al, 2007) and molecular dynamics studies (Babin et al, 2013; Flader et al, 2003) identified small rearrangements of the Glu17 and Arg52 salt bridge and the recognition helix upon binding to DNA, whereas NMR solution structures showed larger conformational changes, which may include disruption of the Glu17 interaction with Arg52 (Billeter et al, 1993; Torrado et al, 2009; Baird-Titus et al, 2006; Chaney et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

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Dynamic Local Polymorphisms in the Gbx1 Homeodomain Induced by DNA Binding

et al. 2016

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SUMMARY The Gastrulation Brain Homeobox 1 (Gbx1) gene encodes the Gbx1 homeodomain that targets TAATTA motifs in dsDNA. Residues Glu17 and Arg52 in Gbx1 form a salt bridge, which is preserved in crystal structures and MD simulations of homologous homeodomain–DNA complexes. In contrast, our NMR studies show that DNA-binding to Gbx1 induces dynamic local polymorphisms, which include breaking of the Glu17–Arg52 salt bridge. To study this interaction, we produced a variant with Glu17Arg and Arg52Glu mutations, which exhibited the same fold as the wild-type protein, but a two-fold reduction in affinity for dsDNA. Analysis of the NMR structures of the Gbx1 homeodomain in the free form, the Gbx1[E17R,R52E] variant, and a Gbx1 homeodomain–DNA complex showed that stabilizing interactions of the Arg52 side chain with the DNA backbone are facilitated by transient breakage of the Glu17–Arg52 salt bridge in the DNA-bound Gbx1.

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NAD(H)‐PEG Swing Arms Improve Both the Activities and Stabilities of Modularly‐Assembled Transhydrogenases Designed with Predictable Selectivities

Massad

Banta

2021

ChemBioChem

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Protein engineering has been used to enhance the activities, selectivities, and stabilities of enzymes. Frequently tradeoffs are observed, where improvements in some features can come at the expense of others. Nature uses modular assembly of active sites for complex, multi‐step reactions, and natural “swing arm” mechanisms have evolved to transfer intermediates between active sites. Biomimetic polyethylene glycol (PEG) swing arms modified with NAD(H) have been explored to introduce synthetic swing arms into fused oxidoreductases. Here we report that increasing NAD(H)‐PEG swing arms can improve the activity of synthetic formate:malate oxidoreductases as well as the thermal and operational stabilities of the biocatalysts. The modular assembly approach enables the KM values of new enzymes to be predictable, based on the parental enzymes. We describe four unique synthetic transhydrogenases that have no native homologs, and this platform could be easily extended for the predictive design of additional synthetic cofactor‐independent transhydrogenases.

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Role of Conserved Salt Bridges in Homeodomain Stability and DNA Binding

Cited by 12 publications

References 38 publications

Dlx5 Homeodomain:DNA Complex: Structure, Binding and Effect of Mutations Related to Split Hand and Foot Malformation Syndrome

Dlx5 Homeodomain:DNA Complex: Structure, Binding and Effect of Mutations Related to Split Hand and Foot Malformation Syndrome

Dynamic Local Polymorphisms in the Gbx1 Homeodomain Induced by DNA Binding

NAD(H)‐PEG Swing Arms Improve Both the Activities and Stabilities of Modularly‐Assembled Transhydrogenases Designed with Predictable Selectivities

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