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1.
FEBS Lett ; 598(18): 2281-2291, 2024 Sep.
Article in English | MEDLINE | ID: mdl-38946055

ABSTRACT

The human FoxP transcription factors dimerize via three-dimensional domain swapping, a unique feature among the human Fox family, as result of evolutionary sequence adaptations in the forkhead domain. This is the case for the conserved glycine and proline residues in the wing 1 region, which are absent in FoxP proteins but present in most of the Fox family. In this work, we engineered both glycine (G) and proline-glycine (PG) insertion mutants to evaluate the deletion events in FoxP proteins in their dimerization, stability, flexibility, and DNA-binding ability. We show that the PG insertion only increases protein stability, whereas the single glycine insertion decreases the association rate and protein stability and promotes affinity to the DNA ligand.


Subject(s)
Forkhead Transcription Factors , Glycine , Proline , Repressor Proteins , Sequence Deletion , Humans , Forkhead Transcription Factors/genetics , Forkhead Transcription Factors/metabolism , Forkhead Transcription Factors/chemistry , Proline/genetics , Proline/metabolism , Proline/chemistry , Glycine/metabolism , Glycine/genetics , Glycine/chemistry , Repressor Proteins/genetics , Repressor Proteins/metabolism , Repressor Proteins/chemistry , Protein Domains , Evolution, Molecular , Protein Stability , Protein Multimerization , DNA/metabolism , DNA/genetics , DNA/chemistry , Protein Binding , Amino Acid Sequence
2.
iScience ; 26(7): 107228, 2023 Jul 21.
Article in English | MEDLINE | ID: mdl-37485372

ABSTRACT

Transcription factors regulate gene expression by binding to DNA. They have disordered regions and specific DNA-binding domains. Binding to DNA causes structural changes, including folding and interactions with other molecules. The FoxP subfamily of transcription factors in humans is unique because they can form heterotypic interactions without DNA. However, it is unclear how they form heterodimers and how DNA binding affects their function. We used computational and experimental methods to study the structural changes in FoxP1's DNA-binding domain when it forms a heterodimer with FoxP2. We found that FoxP1 has complex and diverse conformational dynamics, transitioning between compact and extended states. Surprisingly, DNA binding increases the flexibility of FoxP1, contrary to the typical folding-upon-binding mechanism. In addition, we observed a 3-fold increase in the rate of heterodimerization after FoxP1 binds to DNA. These findings emphasize the importance of structural flexibility in promoting heterodimerization to form transcriptional complexes.

3.
FEBS Lett ; 597(14): 1894-1905, 2023 07.
Article in English | MEDLINE | ID: mdl-37199668

ABSTRACT

Human FoxP proteins share a highly conserved DNA-binding domain that dimerizes via three-dimensional domain swapping, although showing varying oligomerization propensities among its members. Here, we present an experimental and computational characterization of all human FoxP proteins to unravel how their amino acid substitutions impact their folding and dimerization mechanism. We solved the crystal structure of the forkhead domain of FoxP4 to then perform a comparison across all members, finding that their sequence changes impact not only the structural heterogeneity of their forkhead domains but also the protein-protein association energy barrier. Lastly, we demonstrate that the accumulation of a monomeric intermediate is an oligomerization-dependent feature rather than a common aspect of monomers and dimers in this protein subfamily.


Subject(s)
Repressor Proteins , Transcription Factors , Humans , Dimerization , Transcription Factors/metabolism , Amino Acid Sequence , Repressor Proteins/metabolism , Protein Domains , Forkhead Transcription Factors/metabolism , Protein Folding
4.
J Chem Phys ; 158(19)2023 May 21.
Article in English | MEDLINE | ID: mdl-37184020

ABSTRACT

Transcription factors are multidomain proteins with specific DNA binding and regulatory domains. In the human FoxP subfamily (FoxP1, FoxP2, FoxP3, and FoxP4) of transcription factors, a 90 residue-long disordered region links a Leucine Zipper (ZIP)-known to form coiled-coil dimers-and a Forkhead (FKH) domain-known to form domain swapping dimers. We used replica exchange discrete molecular dynamics simulations, single-molecule fluorescence experiments, and other biophysical tools to understand how domain tethering in FoxP1 impacts dimerization at ZIP and FKH domains and how DNA binding allosterically regulates their dimerization. We found that domain tethering promotes FoxP1 dimerization but inhibits a FKH domain-swapped structure. Furthermore, our findings indicate that the linker mediates the mutual organization and dynamics of ZIP and FKH domains, forming closed and open states with and without interdomain contacts, thus highlighting the role of the linkers in multidomain proteins. Finally, we found that DNA allosterically promotes structural changes that decrease the dimerization propensity of FoxP1. We postulate that, upon DNA binding, the interdomain linker plays a crucial role in the gene regulatory function of FoxP1.


Subject(s)
DNA , Transcription Factors , Humans , Transcription Factors/genetics , Transcription Factors/metabolism , Dimerization , DNA/chemistry , Protein Domains , Gene Expression Regulation , Repressor Proteins/chemistry , Repressor Proteins/genetics , Repressor Proteins/metabolism , Forkhead Transcription Factors/chemistry , Forkhead Transcription Factors/genetics , Forkhead Transcription Factors/metabolism
5.
Int J Mol Sci ; 22(19)2021 Sep 24.
Article in English | MEDLINE | ID: mdl-34638644

ABSTRACT

The association of two or more proteins to adopt a quaternary complex is one of the most widespread mechanisms by which protein function is modulated. In this scenario, three-dimensional domain swapping (3D-DS) constitutes one plausible pathway for the evolution of protein oligomerization that exploits readily available intramolecular contacts to be established in an intermolecular fashion. However, analysis of the oligomerization kinetics and thermodynamics of most extant 3D-DS proteins shows its dependence on protein unfolding, obscuring the elucidation of the emergence of 3D-DS during evolution, its occurrence under physiological conditions, and its biological relevance. Here, we describe the human FoxP subfamily of transcription factors as a feasible model to study the evolution of 3D-DS, due to their significantly faster dissociation and dimerization kinetics and lower dissociation constants in comparison to most 3D-DS models. Through the biophysical and functional characterization of FoxP proteins, relevant structural aspects highlighting the evolutionary adaptations of these proteins to enable efficient 3D-DS have been ascertained. Most biophysical studies on FoxP suggest that the dynamics of the polypeptide chain are crucial to decrease the energy barrier of 3D-DS, enabling its fast oligomerization under physiological conditions. Moreover, comparison of biophysical parameters between human FoxP proteins in the context of their minute sequence differences suggests differential evolutionary strategies to favor homoassociation and presages the possibility of heteroassociations, with direct impacts in their gene regulation function.


Subject(s)
Forkhead Transcription Factors/metabolism , Animals , Dimerization , Humans , Kinetics , Models, Molecular , Protein Unfolding , Thermodynamics
6.
Sci Rep ; 10(1): 15986, 2020 Sep 24.
Article in English | MEDLINE | ID: mdl-32973174

ABSTRACT

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

7.
J Mol Biol ; 432(19): 5411-5429, 2020 09 04.
Article in English | MEDLINE | ID: mdl-32735805

ABSTRACT

Forkhead box P (FoxP) proteins are unique transcription factors that spatiotemporally regulate gene expression by tethering two chromosome loci together via functional domain-swapped dimers formed through their DNA-binding domains. Further, the differential kinetics on this dimerization mechanism underlie an intricate gene regulation network at physiological conditions. Nonetheless, poor understanding of the structural dynamics and steps of the association process impedes to link the functional domain swapping to human-associated diseases. Here, we have characterized the DNA-binding domain of human FoxP1 by integrating single-molecule Förster resonance energy transfer and hydrogen-deuterium exchange mass spectrometry data with molecular dynamics simulations. Our results confirm the formation of a previously postulated domain-swapped (DS) FoxP1 dimer in solution and reveal the presence of highly populated, heterogeneous, and locally disordered dimeric intermediates along the dimer dissociation pathway. The unique features of FoxP1 provide a glimpse of how intrinsically disordered regions can facilitate domain swapping oligomerization and other tightly regulated association mechanisms relevant in biological processes.


Subject(s)
DNA/metabolism , Forkhead Transcription Factors/chemistry , Intrinsically Disordered Proteins/chemistry , Repressor Proteins/chemistry , Binding Sites , Forkhead Transcription Factors/metabolism , Humans , Intrinsically Disordered Proteins/metabolism , Molecular Dynamics Simulation , Protein Binding , Protein Domains , Protein Folding , Protein Multimerization , Repressor Proteins/metabolism
8.
Sci Rep ; 9(1): 5441, 2019 04 01.
Article in English | MEDLINE | ID: mdl-30931977

ABSTRACT

Forkhead box P (FoxP) proteins are members of the versatile Fox transcription factors, which control the timing and expression of multiple genes for eukaryotic cell homeostasis. Compared to other Fox proteins, they can form domain-swapped dimers through their DNA-binding -forkhead- domains, enabling spatial reorganization of distant chromosome elements by tethering two DNA molecules together. Yet, domain swapping stability and DNA binding affinity varies between different FoxP proteins. Experimental evidence suggests that the protonation state of a histidine residue conserved in all Fox proteins is responsible for pH-dependent modulation of these interactions. Here, we explore the consequences of the protonation state of another histidine (H59), only conserved within FoxM/O/P subfamilies, on folding and dimerization of the forkhead domain of human FoxP1. Dimer dissociation kinetics and equilibrium unfolding experiments demonstrate that protonation of H59 leads to destabilization of the domain-swapped dimer due to an increase in free energy difference between the monomeric and transition states. This pH-dependence is abolished when H59 is mutated to alanine. Furthermore, anisotropy measurements and molecular dynamics evidence that H59 has a direct impact in the local stability of helix H3. Altogether, our results highlight the relevance of H59 in domain swapping and folding stability of FoxP1.


Subject(s)
Biological Evolution , Forkhead Transcription Factors/metabolism , Histidine/metabolism , Repressor Proteins/metabolism , Histidine/chemistry , Humans , Protons
9.
Front Microbiol ; 8: 2424, 2017.
Article in English | MEDLINE | ID: mdl-29270163

ABSTRACT

The sfk1 (suppressor of four kinase) gene has been mainly studied in Saccharomyces cerevisiae, where it was shown to be involved in growth and thermal stress resistance. This gene is widely conserved within the phylum Ascomycota. Despite this, to date sfk1 has not been studied in any filamentous fungus. Previously, we found that the orthologous of sfk1 was differentially expressed in a strain of Penicillium roqueforti with an altered phenotype. In this work, we have performed a functional characterization of this gene by using RNAi-silencing technology. The silencing of sfk1 in P. roqueforti resulted in decreased apical growth and the promotion of conidial germination, but interesting, it had no effect on conidiation. In addition, the attenuation of the sfk1 expression sensitized the fungus to osmotic stress, but not to thermal stress. RNA-mediated gene-silencing of sfk1 also affected cell wall integrity in the fungus. Finally, the silencing of sfk1 depleted the production of the main secondary metabolites of P. roqueforti, namely roquefortine C, andrastin A, and mycophenolic acid. To the best of our knowledge this is the first study of the sfk1 gene in filamentous fungi.

10.
Biophys J ; 110(11): 2349-2360, 2016 06 07.
Article in English | MEDLINE | ID: mdl-27276253

ABSTRACT

The forkhead family of transcription factors (Fox) controls gene transcription during key processes such as regulation of metabolism, embryogenesis, and immunity. Structurally, Fox proteins feature a conserved DNA-binding domain known as forkhead. Interestingly, solved forkhead structures of members from the P subfamily (FoxP) show that they can oligomerize by three-dimensional domain swapping, whereby structural elements are exchanged between adjacent subunits, leading to an intertwined dimer. Recent evidence has largely stressed the biological relevance of domain swapping in FoxP, as several disease-causing mutations have been related to impairment of this process. Here, we explore the equilibrium folding and binding mechanism of the forkhead domain of wild-type FoxP1, and of two mutants that hinder DNA-binding (R53H) and domain swapping (A39P), using size-exclusion chromatography, circular dichroism, and hydrogen-deuterium exchange mass spectrometry. Our results show that domain swapping of FoxP1 occurs at micromolar protein concentrations within hours of incubation and is energetically favored, in contrast to classical domain-swapping proteins. Also, DNA-binding mutations do not significantly affect domain swapping. Remarkably, equilibrium unfolding of dimeric FoxP1 follows a three-state N2 ↔ 2I ↔ 2U folding mechanism in which dimer dissociation into a monomeric intermediate precedes protein unfolding, in contrast to the typical two-state model described for most domain-swapping proteins, whereas the A39P mutant follows a two-state N ↔ U folding mechanism consistent with the second transition observed for dimeric FoxP1. Also, the free-energy change of the N ↔ U in A39P FoxP1 is âˆ¼2 kcal⋅mol(-1) larger than the I ↔ U transition of both wild-type and R53H FoxP1. Finally, hydrogen-deuterium exchange mass spectrometry reveals that the intermediate strongly resembles the native state. Our results suggest that domain swapping in FoxP1 is at least partially linked to monomer folding stability and follows an unusual three-state folding mechanism, which might proceed via transient structural changes rather than requiring complete protein unfolding as do most domain-swapping proteins.


Subject(s)
Forkhead Transcription Factors/genetics , Forkhead Transcription Factors/metabolism , Repressor Proteins/genetics , Repressor Proteins/metabolism , Chromatography, Gel , Circular Dichroism , Escherichia coli , Humans , Hydrodynamics , Mass Spectrometry , Mutation , Protein Binding , Protein Domains , Protein Folding , Protein Multimerization , Thermodynamics
11.
PLoS One ; 10(3): e0120740, 2015.
Article in English | MEDLINE | ID: mdl-25811807

ABSTRACT

Proteins containing Zn(II)(2)Cys(6) domains are exclusively found in fungi and yeasts. Genes encoding this class of proteins are broadly distributed in fungi, but few of them have been functionally characterized. In this work, we have characterized a gene from the filamentous fungus Penicillium roqueforti that encodes a Zn(II)(2)Cys(6) protein, whose function to date remains unknown. We have named this gene pcz1. We showed that the expression of pcz1 is negatively regulated in a P. roqueforti strain containing a dominant active Gαi protein, suggesting that pcz1 encodes a downstream effector that is negatively controlled by Gαi. More interestingly, the silencing of pcz1 in P. roqueforti using RNAi-silencing technology resulted in decreased apical growth, the promotion of conidial germination (even in the absence of a carbon source), and the strong repression of conidiation, concomitant with the downregulation of the genes of the central conidiation pathway brlA, abaA and wetA. A model for the participation of pcz1 in these physiological processes in P. roqueforti is proposed.


Subject(s)
Fungal Proteins/genetics , Fungal Proteins/metabolism , Penicillium/physiology , Carbon/metabolism , Fungal Proteins/chemistry , Gene Expression Regulation, Fungal , Gene Silencing , Phenotype , Protein Subunits , RNA Interference , RNA, Small Interfering/genetics
12.
Appl Biochem Biotechnol ; 172(1): 524-32, 2014 Jan.
Article in English | MEDLINE | ID: mdl-24096527

ABSTRACT

Despite their potential biotechnological applications, cold-active xylanolytic enzymes have been poorly studied. In this work, 38 fungi isolated from marine sponges collected in King George Island, Antarctica, were screened as new sources of cold-active xylanases. All of them showed xylanase activity at 15 and 23 °C in semiquantitative plate assays. One of these isolates, Cladosporium sp., showed the highest activity and was characterized in detail. Cladosporium sp. showed higher xylanolytic activity when grown on beechwood or birchwood xylan and wheat bran, but wheat straw and oat bran were not so good inducers of this activity. The optimal pH for xylanase activity was 6.0, although pH stability was slightly wider (pH 5-7). On the other hand, Cladosporium sp. showed high xylanase activity at low temperatures and very low thermal stability. Interestingly, thermal stability was even lower after culture media were removed and replaced by buffer, suggesting that low molecular component(s) of the culture media could be important in the stabilization of cold-active xylanase activity. To the best of our knowledge, this study is the first report on extracellular xylanase production by fungi associated with Antarctic marine sponges.


Subject(s)
Aquatic Organisms/microbiology , Cladosporium/metabolism , Cold Temperature , Endo-1,4-beta Xylanases/biosynthesis , Endo-1,4-beta Xylanases/metabolism , Porifera/microbiology , Animals , Antarctic Regions , Cladosporium/isolation & purification , Endo-1,4-beta Xylanases/chemistry , Enzyme Stability , Hydrogen-Ion Concentration , Hydrolysis , Molecular Weight , Temperature , Xylans/metabolism
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