Search

SMNDC1 is a splicing factor that binds arginine methylation with its Tudor domain. Here, the authors study the protein’s phase-separating behavior and develop small-molecule Tudor domain inhibitors that perturb SMNDC1 function.

The authors find that TDP-43 loss of function—the pathology defining the neurodegenerative conditions ALS and FTD—induces novel mRNA polyadenylation events, which have different effects, including an increase in RNA stability, leading to higher protein levels.

A comparison of alpha diversity (number of plant species) and dark diversity (species that are currently absent from a site despite being ecologically suitable) demonstrates the negative effects of regional-scale anthropogenic activity on plant diversity.

Understanding how complexes, such as Mediator, that act at diverse promoters interact with gene-specific transcription factors is key to understanding transcriptional regulation. The solution structure of Med25 (Arc92) is now presented and its interaction with helices on the VP16 activator elucidated. The Med25 interface is found to be conserved, but VP16 is revealed to be more diverse in its interaction with different interactors.

The specific recognition of a proline-rich motif in the intrinsically disordered region of SF1 by the PRPF40A tandem WW domains is modulated by an intramolecular autoinhibition, suggesting a general mechanism to enhance WW binding selectivity.

Missing modality challenges longitudinal omics studies. Here, the authors introduce LEOPARD, a pioneering neural network that uses style transfer to re-entangle omics data, enabling robust imputation and unlocking fresh insights into predictive healthcare and biological temporal dynamics.

The RNA binding protein RBM5 regulates alternative splicing of genes implicated in cancer. Here the authors show structural mechanisms how multiple RNA binding domains of RBM5 cooperate to recognize specific target RNA sequences.

The crystal structure of the RNA binding domains of Sxl and Unr with msl2 RNA shows that interwoven interactions establish cooperative assembly of the ternary complex, highlighting how binding of relatively general RNA binding domains to RNA can result in a unique and specific protein–RNA architecture.

The DNA-dependent protease SPRTN cleaves toxic DNA-protein crosslinks (DPCs). Here, the authors show that SPRTN is activated by DPC-ubiquitylation through an allosteric ubiquitin binding interface. This regulatory mechanism enables precise control of SPRTN activity during DNA repair.

p23 is a co-chaperone of Hsp90 but its mode of action is mechanistically not well understood. Here, the authors combine in vitro and yeast in vivo assays, biochemical measurements and NMR experiments to characterize p23 and identify two conserved helical elements in the intrinsically disordered C-terminal tail of p23 that together with the folded domain of p23 regulate the Hsp90 ATPase activity and affect the binding and maturation of Hsp90 clients.

The soluble bioactive form of the transmembrane protein fibronectin type III domain containing 4 (sFNDC4) has anti-inflammatory effects and improves insulin sensitivity. Here the authors show that liver derived sFNDC4 signals through adipose tissue GPCR GPR116 to promote insulin-mediated glucose uptake.

Although the formation of beads on filaments of saliva drawn between two solid surfaces is familiar to most people, the precise mechanism responsible for such behaviour has been hotly debated. Simulations reveal that inertial effects play a pivotal role in this process.

Dräger et al. establish a rapid, scalable platform for iPSC-derived microglia. CRISPRi/a screens uncover roles of disease-associated genes in phagocytosis, and regulators of disease-relevant microglial states that can be targeted pharmacologically.

Import of proteins into peroxisomes depends on PEX5, PEX13 and PEX14. Here the authors obtain crystal structures and NMR data to show the recognition of diaromatic peptide motifs on a noncanonical surface of the PEX13 SH3 domain, revealing a dynamic network which modulates peroxisomal matrix import.

Roquin is an RNA-binding protein that prevents autoimmunity by limiting expression of receptors such as Ox40. Here, the authors identify an RNA structure that they describe as an alternative decay element, and they characterise its interaction with Roquin using structural and biochemical techniques.

So far only a few compounds have been reported as splicing modulators. Here, the authors combine high-throughput screening, chemical synthesis, NMR, X-ray crystallography with functional studies and develop phenothiazines as inhibitors for the U2AF Homology Motif (UHM) domains of proteins that regulate splicing and show that they inhibit early spliceosome assembly on pre-mRNA substrates in vitro.

Roquin controls T-cell activity through interactions with mRNAs of stimulatory receptors. Structural and functional elucidation of its RNA-binding domain reveals how it interacts with constitutive decay elements in the 3' UTR of its targets to regulate their expression.

Regulation of thymocyte development by RNA-binding proteins is not fully characterized. Here the authors show the RBP ARPP21 interacting with the Rag1 3’-UTR to promote Rag1 expression, TCR rearrangement and an increased diversity of the TCR repertoire and that ARPP21 is down regulated by TCR stimulation.

In the absence of GPX4, FSP1 regenerates ubiquinol from the oxidized form, ubiquinone, using NAD(P)H and suppresses phospholipid peroxidation and ferroptosis in cells.

Multidomain RNA-binding proteins recognize specific target sequences through mechanisms that are not well understood. Here the authors present an integrated approach to define the RNA-binding specificity and RNP topology and apply it to the analysis of the prototypical multidomain RNA-binding protein IMP3.

Buried charged networks in proteins are often important for their biological functionality and are believed to destabilise the protein fold. Here, the authors combine computational design, MD simulations, biophysical experiments, NMR and X-ray crystallography to design and characterise artificial 4α-helical proteins with buried charged elements. They analyse their conformational landscapes and observe that the ion-pairs are stabilised by amphiphilic residues that electrostatically shield the charged motif, which increases structural stability.

The Staufen family of RNA-binding proteins are conserved microtubule dependent mRNA transporter factors. Here the authors use biochemical and functional approaches to characterize the RNA-binding properties of mouse Staufen 2 and study the mRNA binding capacity of its two domains dsRBDs 1 and 2.

hnRNP A1 is an auxiliary factor that promotes the Microprocessor-mediated processing of pri-mir-18a, of the oncomiR-1 cluster. Here the authors employ an integrative structural biology approach and provide insights into the molecular mechanism of how hnRNP A1 facilitates pri-mir-18a biogenesis.

PEX19 is a chaperone and import receptor for peroxisomal membrane proteins (PMPs). Here the authors present the structure of the farnesylated C-terminal domain of PEX19, and its interaction with PMPs reveals how the farnesyl moiety allosterically reshapes the PMP binding surface and modulates PEX19 function.

Dimethylated arginine (DMA) marks are recognized by Tudor domain–containing proteins and play a role in the assembly of ribonucleoprotein complexes. Structural analysis of prototypic Tudor domains from SMN and SPF30 in complex with DMA reveals the recognition mode of DMA, enabling the design of an optimized binding pocket.

The chloroplast signal recognition particle delivers LHCPs to the thylakoid membrane by interaction of cpSRP43 with the Alb3 insertase. Here the authors decipher the specific recognition of the Alb3 C-terminal tail within the interface of two communicating chromodomains by structural biochemistry.

Little is known about how climate change impacts glacier-fed streams (GFSs) microbiomes. Here, using a modelling framework based on global GFS metagenomic, climatic and environmental data the authors predict future increases in GFS bacterial biomass and diversity, but potential loss of clades adapted to extreme conditions.

A candidate-based genetic screen in Drosophila expressing 30 G₄C₂-repeat-containing RNAs finds that RanGAP, a key regulator of nucleocytoplasmic transport, is a potent suppressor of neurodegeneration; the defects caused by the G₄C₂ repeat expansions can be rescued with antisense oligonucleotides or small molecules targeting the G-quadruplexes.

Extensive mutational analyses of ferroptosis suppressor protein-1 (FSP1) reveal its molecular mechanism in ferroptosis prevention and uncover the mechanism of action of the FSP1 inhibitor iFSP1 and a new species-independent FSP1 inhibitor, viFSP1.

Here, the authors show how binding of talin and kindlin to the β-integrin cytoplasmic tail increases talin and decreases kindlin affinity toward it, providing insights into mechanisms of integrin activation.

Membraneless organelles are liquid-liquid phase-separated droplets whose behaviour can be regulated by chemical reactions, but this process is poorly understood. Here, the authors report model membraneless organelles based on coacervate droplets that show fuel-driven dynamic behaviour and concentrate functional RNA.

Lacagnina et al. show that extinction training suppresses the associated hippocampal fear engram and generates a distinct extinction engram. Reactivation of extinction engram cells reduces fear, while reactivation of fear engram cells causes fear relapse.

It is unclear how unassembled secretory pathway proteins are discriminated from misfolded ones. Here the authors combine biophysical and cellular experiments to study the folding of heterodimeric interleukin 23 and describe how ER chaperones recognize unassembled proteins and aid their assembly into protein complexes while preventing the premature degradation of unassembled units.

The chaperone Hsp90 uses the free energy from ATP hydrolysis to control the folding of client proteins in eukaryotic cells. Here the authors provide mechanistic insights into how its catalytic activity is coupled to conformational changes by combining large-scale molecular simulations with NMR, FRET and SAXS experiments.

The human RNA exosome contains a nuclear co-factor MTR4, which unwinds structural RNAs and recruits adaptors for different RNA processing and decay pathways. Here the authors uncover new variations of the arch-interacting motif (AIM) in NVL and ZCCHC8 and characterise their interaction with MTR4.

Histone lysine methylation has a central role in transcriptional regulation and has recently been linked to DNA damage repair. Now it has been shown that the DNA damage repair factor 53BP1 is recruited to DNA double-strand breaks by its tandem tudor domain, which specifically recognizes histone H4 dimethylated at lysine 20.

An inhibitor of the ferroptosis-suppressing FSP1 induces phase separation of FSP1, thereby impairing its function and reducing tumour growth.

Nuclear chromodomain-containing proteins read the epigenetic code by recognizing methylated lysine residues in histone tails. Structural analysis of the cytoplasmic chloroplast signal recognition particle subunit cpSRP34 in complex with the cpSRP54 subunit C-terminal tail comprising an arginine-rich motif reveals that a twinned aromatic cage reads two neighboring nonmethylated arginine residues and adapts chromodomains to a function outside the nucleus.