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The bHLH proteins are a family of eukaryotic transcription factors regulating expression of a wide range of genes involved in cell differentiation and development. They contain the Helix-Loop-Helix (HLH) domain, preceded by a stretch of basic residues, which are responsible for dimerization and binding to E-box sequences. In addition to the well-preserved DNA-binding bHLH domain, these proteins may contain various additional domains determining the specificity of performed transcriptional regulation. According to this, the family has been divided into distinct classes. Our aim was to emphasize the significance of existing disordered regions within the bHLH transcription factors for their functionality. Flexible, intrinsically disordered regions containing various motives and specific sequences allow for multiple interactions with transcription co-regulators. Also, based on in silico analysis and previous studies, we hypothesize that the bHLH proteins have a general ability to undergo spontaneous phase separation, forming or participating into liquid condensates which constitute functional centers involved in transcription regulation. We shortly introduce recent findings on the crucial role of the thermodynamically liquid-liquid driven phase separation in transcription regulation by disordered regions of regulatory proteins. We believe that further experimental studies should be performed in this field for better understanding of the mechanism of gene expression regulation (among others regarding oncogenes) by important and linked to many diseases the bHLH transcription factors.

Background NeuroD1 and NeuroD2, members of the bHLH transcription factors family, are key regulators of nervous system development and function. While they share similar roles in neuronal regulation, their divergent expression patterns and specialized functions suggest the complexity of transcriptional control they perform. The activity of bHLH TFs depends on tightly regulated intracellular trafficking orchestrated by NLSs and/or NESs located within the protein’s sequences. A detailed characterization of these molecular motifs is essential to understand the mechanisms regulating NeuroD1 and NeuroD2 functions. Methods We prepared cDNA vector that enabled expression of the full-length and truncated variants of NeuroD1 and NeuroD2 fused to YFP in COS-7 and N2a cells. Confocal microscopy was used to assess intracellular localization and to identify the location of motifs presenting NLS, NES, and NoLS activity. Results We demonstrated that previously documented NLS (NLS1), conserved both in NeuroD1 and NeuroD2 also presents NoLS (NoLS1) activity, revealing unexpected dual functionality. Additionally, we identified overlapping NLS2 and NES1 within the bHLH domains of both proteins. Notably, NeuroD2 harbours distinct NLS3 and a second NoLS (NoLS2) motifs, located in the C-terminal region. These elements, suggest differentiated regulation and specialization between the homologs. Conclusions Our study reveals a surprisingly complex network of overlapping localization signals in NeuroD1 and NeuroD2 that regulate their cyto-nuclear trafficking. The presence of multiple, potentially competing signals suggests that their activity may be fine-tuned by specific ligands or interacting partners, adding further complexity to their regulation. These findings provide novel insight into how subcellular localization contributes to the functional divergence of homologous transcription factors.

Pitt-Hopkins Syndrome (PTHS) is a rare neurodevelopmental disorder caused by mutations in the TCF4 gene (18q21.2), encoding the transcription factor 4 (TCF4). This protein is critical for central nervous system development and neuronal maturation. Mutations in TCF4 , which range from point mutations to large deletions, result in varying clinical severity, including intellectual disability (ID), motor impairments, and autistic features. Despite its rarity, PTHS has gained increasing attention due to advances in understanding the genetic and molecular mechanisms underlying TCF4 function. Recent research has enhanced diagnostic approaches, including genetic testing techniques like genome sequencing, enabling more accurate identification of the disorder. Despite the evident enhancement in the PTHS management from a medical standpoint, the molecular underpinnings of the disorder progression remain puzzling. This is particularly the case where the disease is caused by point mutations. This review summarizes the latest findings on TCF4 function in PTHS, discusses the variability in mutation effects, highlights current diagnostic and therapeutic advancements, and attempts to explain the molecular bases of mutated TCF4 malfunctionality.

Transcription factor 4 (TCF4) is a class I basic helix-loop-helix (bHLH) transcription factor which regulates the neurogenesis and specialization of cells. TCF4 also plays an important role in the development and functioning of the immune system. Additionally, TCF4 regulates the development of Sertoli cells and pontine nucleus neurons, myogenesis, melanogenesis and epithelial-mesenchymal transition. The ability of transcription factors to fulfil their function often depends on their intracellular trafficking between the nucleus and cytoplasm of the cell. The trafficking is regulated by specific sequences, i.e. the nuclear localization signal (NLS) and the nuclear export signal (NES). We performed research on the TCF4 trafficking regulating sequences by mapping and detailed characterization of motifs potentially acting as the NLS or NES. We demonstrate that the bHLH domain of TCF4 contains an NLS that overlaps two NESs. The results of in silico analyses show high conservation of the sequences, especially in the area of the NLS and NESs. This high conservation is not only between mouse and human TCF4, but also between TCF4 and other mammalian E proteins, indicating the importance of these sequences for the functioning of bHLH class I transcription factors.

Background Transcription factor 4 (TCF4) is a member of the basic helix-loop-helix (bHLH) family of transcription factors that guides proper embryogenesis, particularly neurogenesis, myogenesis, heart development and hematopoiesis. The interaction of TCF4 with DNA is dependent on the presence of a conserved bHLH domain, particularly the presence of a basic (b) motif. Most mutations in the Tcf4 gene are either associated with the development of serious nervous system disorders, such as Pitt-Hopkins syndrome or schizophrenia, or are lethal. Although TCF4 is essential for the proper development and function of the human body, there is a lack of fundamental knowledge about the structure of TCF4 since structural studies were previously limited exclusively to its bHLH. Methods Recombinant full-length TCF4 was expressed in bacterial cells and purified using chromatographic techniques. To compare the properties of TCF4 in its apo and holo form, we determined the dissociation constant (K D ) of the TCF4:DNA complex using independent methods, including fluorescence polarization (FP), electrophoretic mobility shift assay (EMSA), and fluorescence correlation spectroscopy (FCS). Then we compared the properties of TCF4 in its apo and holo form in relation to the changes of the conformation of the polypeptide chain (hydrogen/deuterium exchange mass spectrometry; HDX-MS), hydrodynamic properties (e.g., sedimentation-velocity analytical ultracentrifugation; SV-AUC), and stability (thermal shift, circular dichroism; CD). Results We demonstrate the molecular characteristics of TCF4, the dimer of which is one of the largest intrinsically disordered proteins (IDPs) described to date. According to our findings, the structure of TCF4 is extensively disordered. Only the bHLH domain exhibits a stable fold. Strikingly, Ephrussi-box (E-box) binding via the bHLH domain has no significant effect on the disordered nature of TCF4, but it does influence the dynamic of bHLH and stability of the protein. Conclusions We suggest that bHLH plays the role of an anchor localizing TCF4 to specific gene sequences. The dual nature of the TCF4 structure and the fact that the intrinsically disordered regions (IDRs) represent most of the protein sequence, suggest that TCF4 may act as a hub transcription factor regulating the expression of specific genes through the interaction of IDRs with gene-specific partners.

The Drosophila melanogaster Germ cell-expressed protein (GCE) is a paralog of the juvenile hormone (JH) receptor - Methoprene tolerant protein (MET). Both proteins mediate JH function, preventing precocious differentiation during D. melanogaster development. Despite that GCE and MET are often referred to as equivalent JH receptors, their functions are not fully redundant and show tissue specificity. Both proteins belong to the family of bHLH-PAS transcription factors. The similarity of their primary structure is limited to defined bHLH and PAS domains, while their long C-terminal fragments (GCEC, METC) show significant differences and are expected to determine differences in GCE and MET protein activities. In this paper we present the structural characterization of GCEC as a coil-like intrinsically disordered protein (IDP) with highly elongated and asymmetric conformation. In comparison to previously characterized METC, GCEC is less compacted, contains more molecular recognition elements (MoREs) and exhibits a higher propensity for induced folding. The NMR shifts perturbation experiment and pull-down assay clearly demonstrated that the GCEC fragment is sufficient to form an interaction interface with the ligand binding domain (LBD) of the nuclear receptor Fushi Tarazu factor-1 (FTZ-F1). Significantly, these interactions can force GCEC to adopt more fixed structure that can modulate the activity, structure and functions of the full-length receptor. The discussed relation of protein functionality with the structural data of inherently disordered GCEC fragment is a novel look at this protein and contributes to a better understanding of the molecular basis of the functions of the C-terminal fragments of the bHLH-PAS family. 2UuA8w5_5agRn7KffXMuPj Video abstract.

Methoprene tolerant protein (Met) has recently been confirmed as the long-sought juvenile hormone (JH) receptor. This protein plays a significant role in the cross-talk of the 20-hydroxyecdysone (20E) and JH signalling pathways, which are important for control of insect development and maturation. Met belongs to the basic helix-loop-helix/Per-Arnt-Sim (bHLH-PAS) family of transcription factors. In these proteins, bHLH domains are typically responsible for DNA binding and dimerization, whereas the PAS domains are crucial for the choice of dimerization partner and the specificity of target gene activation. The C-terminal region is usually responsible for the regulation of protein complex activity. The sequence of the Met C-terminal region (MetC) is not homologous to any sequence deposited in the Protein Data Bank (PDB) and has not been structurally characterized to date. In this study, we show that the MetC exhibits properties typical for an intrinsically disordered protein (IDP). The final averaged structure obtained with small angle X-ray scattering (SAXS) experiments indicates that intrinsically disordered MetC exists in an extended conformation. This extended shape and the long unfolded regions characterise proteins with high flexibility and dynamics. Therefore, we suggest that the multiplicity of conformations adopted by the disordered MetC is crucial for its activity as a biological switch modulating the cross-talk of different signalling pathways in insects.

For a long time, entomopathogenic fungi were considered alternative biological control factors. Recently, these organisms were shown to fulfill additional roles supporting plants’ development, improving their resistance to disease and survival under stress conditions. Considering the documented interactions of B. bassiana with a wide range of plants, we aimed to evaluate the impact of aqueous extracts of the fungus on the growth of an agriculturally significant plant—wheat. The usage of fungal extracts instead of fungi could be beneficial especially in unfavorable, environmentally speaking, regions. Selected dilutions of the crude extract obtained under different pH and temperature conditions were used to establish the optimal method of extraction. Plant growth parameters such as length, total fresh weight, and chlorophyll composition were evaluated. Additionally, the antibacterial activity of extracts was tested to exclude negative impacts on the beneficial soil microorganisms. The best results were obtained after applying extracts prepared at 25 °C and used at 10% concentration. Enhancement of the tested wheat’s growth seems to be related to the composition of the extracts, which we documented as a rich source of macro- and microelements. Our preliminary results are the first confirming the potential of fungal water extracts as factors promoting plant growth. Further detailed investigation needs to be carried out to confirm the effects in real environment conditions. Additionally, the consistency of the plant growth stimulation across different entomopathogenic fungi and agriculturally used plant species should be tested.

Drosophila melanogaster germ cell-expressed protein (GCE) belongs to the family of bHLH-PAS transcription factors that are the regulators of gene expression networks that determine many physiological and developmental processes. GCE is a homolog of D. melanogaster methoprene tolerant protein (MET), a key mediator of anti-metamorphic signaling in insects and the putative juvenile hormone receptor. Recently, it has been shown that the functions of MET and GCE are only partially redundant and tissue specific. The ability of bHLH-PAS proteins to fulfill their function depends on proper intracellular trafficking, determined by specific sequences, i.e. the nuclear localization signal (NLS) and the nuclear export signal (NES). Nevertheless, until now no data has been published on the GCE intracellular shuttling and localization signals. We performed confocal microscopy analysis of the subcellular distribution of GCE fused with yellow fluorescent protein (YFP) and YFP-GCE derivatives which allowed us to characterize the details of the subcellular traffic of this protein. We demonstrate that GCE possess specific pattern of localization signals, only partially consistent with presented previously for MET. The presence of a strong NLS in the C-terminal part of GCE, seems to be unique and important feature of this protein. The intracellular localization of GCE appears to be determined by the NLSs localized in PAS-B domain and C-terminal fragment of GCE, and NESs localized in PAS-A, PAS-B domains and C-terminal fragment of GCE. NLSs activity can be modified by juvenile hormone (JH) and other partners, likely 14-3-3 proteins.

The basic helix–loop–helix/Per-ARNT-SIM (bHLH–PAS) proteins are a class of transcriptional regulators, commonly occurring in living organisms and highly conserved among vertebrates and invertebrates. These proteins exhibit a relatively well-conserved domain structure: the bHLH domain located at the N-terminus, followed by PAS-A and PAS-B domains. In contrast, their C-terminal fragments present significant variability in their primary structure and are unique for individual proteins. C-termini were shown to be responsible for the specific modulation of protein action. In this review, we present the current state of knowledge, based on NMR and X-ray analysis, concerning the structural properties of bHLH–PAS proteins. It is worth noting that all determined structures comprise only selected domains (bHLH and/or PAS). At the same time, substantial parts of proteins, comprising their long C-termini, have not been structurally characterized to date. Interestingly, these regions appear to be intrinsically disordered (IDRs) and are still a challenge to research. We aim to emphasize the significance of IDRs for the flexibility and function of bHLH–PAS proteins. Finally, we propose modern NMR methods for the structural characterization of the IDRs of bHLH–PAS proteins.