Wadjet-Keeping a watchful eye on circular DNA.

The structural maintenance of chromosomes (SMC)-family Wadjet complex restricts plasmid transformation in bacteria through a distinctive mechanism coupling DNA loop extrusion and cleavage. In this issue of Structure, Roisné-Hamelin et al. report the biochemical reconstitution and structure of a type II Wadjet complex, revealing a shared overall mechanism and notable architectural differences compared to related type I complexes.

Bipartite chromatin recognition by Hop1 from two diverged Holozoa.

In meiosis, ploidy reduction is driven by a complex series of DNA breakage and recombination events between homologous chromosomes, orchestrated by meiotic HORMA domain proteins (HORMADs). Meiotic HORMADs possess a central chromatin binding region (CBR) whose architecture varies across eukaryotic groups. Here, we determine high-resolution crystal structures of the meiotic HORMAD CBR from two diverged aquatic Holozoa, and , which reveal tightly associated plant homeodomain (PHD) and winged helix-turn-helix (wHTH) domains.

An allosteric network governs Tom70 conformational dynamics to coordinate mitochondrial protein import.

Tom70 mediates mitochondrial protein import by coordinating the transfer of cytosolic preproteins from Hsp70/Hsp90 to the translocase of the outer membrane (TOM) complex. In humans, the cytosolic domain of Tom70 (Tom70c) is entirely -helical and comprises modular TPR motifs divided into an N-terminal chaperone-binding domain (NTD) and a C-terminal preprotein-binding domain (CTD). However, the mechanisms linking these functional regions remain poorly understood.

Bipartite chromatin recognition by Hop1 from two diverged holozoa.

In meiosis, ploidy reduction is driven by a complex series of DNA breakage and recombination events between homologous chromosomes, orchestrated by meiotic HORMA domain proteins (HORMADs). Meiotic HORMADs possess a central chromatin binding region (CBR) whose architecture varies across eukaryotic groups. Here, we determine high-resolution crystal structures of the meiotic HORMAD CBR from two diverged aquatic holozoa, and , which reveal tightly-associated PHD and winged helix-turn-helix (wHTH) domains.

TRIM37 prevents ectopic spindle pole assembly by peptide motif recognition and substrate-dependent oligomerization.

Tightly controlled duplication of centrosomes, the primary microtubule-organizing centers of animal cells, ensures bipolarity of the mitotic spindle and accurate chromosome segregation. The RING-B-box-coiled coil ubiquitin ligase tripartite motif-containing protein 37 (TRIM37), whose loss is associated with elevated chromosome missegregation and the tumor-prone human developmental disorder Mulibrey nanism, prevents the formation of ectopic spindle poles assembling around structured condensates that contain the centrosomal protein centrobin. Here, we show that TRIM37's tumor necrosis factor receptor-associated factor (TRAF) domain, which is unique in the extended TRIM family, engages peptide motifs in centrobin to suppress condensate formation.

Stathmin-2 enhances motor axon regeneration after injury independent of its binding to tubulin.

Stathmin-2 (also known as ) is encoded by the gene, whose mRNA is one of the most abundantly expressed in human motor neurons. In almost all instances of ALS and other TDP-43 proteinopathies, stathmin-2 encoding mRNAs are cryptically spliced and polyadenylated in motor neurons, a pathogenic consequence of nuclear loss of function of the RNA binding protein TDP-43. While stathmin-2 has been shown to enhance regeneration after axonal injury to axons of cultured motor neurons, here, we show that after crush injury within the adult murine nervous system of wild-type or stathmin-2-null mice, the presence of stathmin-2 reduces axonal and neuromuscular junction degeneration and stimulates reinnervation and functional recovery.

Unveiling the multifaceted domain polymorphism of the Menshen antiphage system.

Recent advances have significantly enriched our understanding of complex bacteria-phage interactions. To date, over one hundred bacterial antiphage systems have been identified, yet the mechanisms of many, including the recently discovered Menshen system, remain elusive. We employed comparative genomics and protein bioinformatics for a systematic investigation of the Menshen system, focusing on its organization, structure, function, and evolution.

Structural diversity and oligomerization of bacterial ubiquitin-like proteins.

Bacteria possess a variety of operons with homology to eukaryotic ubiquitination pathways that encode predicted E1, E2, E3, deubiquitinase, and ubiquitin-like proteins. Some of these pathways have recently been shown to function in anti-bacteriophage immunity, but the biological functions of others remain unknown. Here, we show that ubiquitin-like proteins in two bacterial operon families show surprising architectural diversity, possessing one to three β-grasp domains preceded by diverse N-terminal domains.

Sequential membrane- and protein-bound organelles compartmentalize genomes during phage infection.

Many eukaryotic viruses require membrane-bound compartments for replication, but no such organelles are known to be formed by prokaryotic viruses. Bacteriophages of the Chimalliviridae family sequester their genomes within a phage-generated organelle, the phage nucleus, which is enclosed by a lattice of the viral protein ChmA. We show that inhibiting phage nucleus formation arrests infections at an early stage in which the injected phage genome is enclosed within a membrane-bound early phage infection (EPI) vesicle.

The synaptonemal complex aligns meiotic chromosomes by wetting.

During meiosis, the parental chromosomes are drawn together to enable exchange of genetic information. Chromosomes are aligned through the assembly of a conserved interface, the synaptonemal complex, composed of a central region that forms between two parallel chromosomal backbones called axes. Here, we identify the axis-central region interface in , containing a conserved positive patch on the axis component HIM-3 and the negative C terminus of the central region protein SYP-5.

Short 5' UTRs serve as a marker for viral mRNA translation inhibition by the IFIT2-IFIT3 antiviral complex.

Recognition of "non-self" nucleic acids, including cytoplasmic dsDNA, dsRNA, or mRNAs lacking proper 5' cap structures, is critical for the innate immune response to viruses. Here, we demonstrate that short 5' untranslated regions (UTRs), a characteristic of many viral mRNAs, can also serve as a molecular pattern for innate immune recognition via the interferon-induced proteins IFIT2 and IFIT3. The IFIT2-IFIT3 heterodimer, formed through an intricate domain swap structure resolved by cryo-EM, mediates viral mRNA 5' end recognition, translation inhibition, and ultimately antiviral activity.

A bacterial NLR-related protein recognizes multiple unrelated phage triggers to sense infection.

Immune systems must rapidly sense viral infections to initiate antiviral signaling and protect the host. Bacteria encode >100 distinct viral (phage) defense systems and each has evolved to sense crucial components or activities associated with the viral lifecycle. Here we used a high-throughput AlphaFold-multimer screen to discover that a bacterial NLR-related protein directly senses multiple phage proteins, thereby limiting immune evasion.

Bacterial Shedu immune nucleases share a common enzymatic core regulated by diverse sensor domains.

Prokaryotes possess diverse anti-bacteriophage immune systems, including the single-protein Shedu nuclease. Here, we reveal the structural basis for activation of Bacillus cereus Shedu. Two cryoelectron microscopy structures of Shedu show that it switches between inactive and active states through conformational changes affecting active-site architecture, which are controlled by the protein's N-terminal domain (NTD).

Rational design yields RNA-binding zinc finger domains with altered sequence specificity.

Targeting and manipulating endogenous RNAs in a sequence-specific manner is essential for both understanding RNA biology and developing RNA-targeting therapeutics. RNA-binding zinc fingers (ZnFs) are excellent candidates as designer proteins to expand the RNA-targeting toolbox, due to their compact size and modular sequence recognition. Currently, little is known about how the sequence of RNA-binding ZnF domains governs their binding site specificity.

Loop-extrusion-mediated plasmid DNA cleavage by the bacterial SMC Wadjet complex.

Structural maintenance of chromosomes (SMC) complexes play pivotal roles in genome organization and maintenance across all domains of life. In prokaryotes, SMC-family Wadjet complexes structurally resemble the widespread MukBEF but serve a defensive role by inhibiting plasmid transformation. We previously showed that Wadjet specifically cleaves plasmid DNA; however, the molecular mechanism underlying plasmid recognition remains unclear.

Mechanistic basis for protein conjugation in a diverged bacterial ubiquitination pathway.

Ubiquitination is a fundamental and highly conserved protein post-translational modification pathway, in which ubiquitin or a ubiquitin-like protein (Ubl) is typically conjugated to a lysine side chain of a target protein. Ubiquitination is a multistep process initiated by adenylation of the Ubl C-terminus, followed by sequential formation of 2-3 Ubl~cysteine thioester intermediates with E1, E2, and E3 proteins before formation of the final Ubl-lysine isopeptide bond. Ubiquitination is conserved across eukaryotes, and recent work has also revealed at least two related bacterial pathways that perform protein conjugation in the context of antiphage immunity.

Bacterial WYL domain transcriptional repressors sense single-stranded DNA to control gene expression.

Bacteria encode a wide array of immune systems to protect themselves against ubiquitous bacteriophages and foreign DNA elements. While these systems' molecular mechanisms are becoming increasingly well known, their regulation remains poorly understood. Here, we show that an immune system-associated transcriptional repressor of the wHTH-WYL-WCX family, CapW, directly binds single-stranded DNA to sense DNA damage and activate expression of its associated immune system.

TRIM37 employs peptide motif recognition and substrate-dependent oligomerization to prevent ectopic spindle pole assembly.

Tightly controlled duplication of centrosomes, the major microtubule-organizing centers of animal cells, ensures bipolarity of the mitotic spindle and accurate chromosome segregation. The RBCC (RING-B-box-coiled coil) ubiquitin ligase TRIM37, whose loss is associated with elevated chromosome missegregation and the tumor-prone developmental human disorder Mulibrey nanism, prevents the formation of ectopic spindle poles that assemble around structured condensates containing the centrosomal protein centrobin. Here, we show that TRIM37's TRAF domain, unique in the extended TRIM family, engages peptide motifs in centrobin to suppress condensate formation.

Bacteriophage Φ21's receptor-binding protein evolves new functions through destabilizing mutations that generate non-genetic phenotypic heterogeneity.

How viruses evolve to expand their host range is a major question with implications for predicting the next pandemic. Gain-of-function experiments have revealed that host-range expansions can occur through relatively few mutations in viral receptor-binding proteins, and the search for molecular mechanisms that explain such expansions is underway. Previous research on expansions of receptor use in bacteriophage λ has shown that mutations that destabilize λ's receptor-binding protein cause it to fold into new conformations that can utilize novel receptors but have weakened thermostability.

High-sensitivity in situ capture of endogenous RNA-protein interactions in fixed cells and primary tissues.

RNA-binding proteins (RBPs) have pivotal functions in RNA metabolism, but current methods are limited in retrieving RBP-RNA interactions within endogenous biological contexts. Here, we develop INSCRIBE (IN situ Sensitive Capture of RNA-protein Interactions in Biological Environments), circumventing the challenges through in situ RNA labeling by precisely directing a purified APOBEC1-nanobody fusion to the RBP of interest. This method enables highly specific RNA-binding site identification across a diverse range of fixed biological samples such as HEK293T cells and mouse brain tissue and accurately identifies the canonical binding motifs of RBFOX2 (UGCAUG) and TDP-43 (UGUGUG) in native cellular environments.

The synaptonemal complex aligns meiotic chromosomes by wetting.

During meiosis, the parental chromosomes are drawn together to enable exchange of genetic information. Chromosomes are aligned through the assembly of a conserved interface, the synaptonemal complex, composed of a central region that forms between two parallel chromosomal backbones called axes. Here we identify the axis-central region interface in , containing a conserved positive patch on the axis component HIM-3 and the C-terminus of the central region protein SYP-5.