Arrayed CRISPR libraries for the genome-wide activation, deletion and silencing of human protein-coding genes.

Arrayed CRISPR libraries extend the scope of gene-perturbation screens to non-selectable cell phenotypes. However, library generation requires assembling thousands of vectors expressing single-guide RNAs (sgRNAs). Here, by leveraging massively parallel plasmid-cloning methodology, we show that arrayed libraries can be constructed for the genome-wide ablation (19,936 plasmids) of human protein-coding genes and for their activation and epigenetic silencing (22,442 plasmids), with each plasmid encoding an array of four non-overlapping sgRNAs designed to tolerate most human DNA polymorphisms.

The need for Cre-loci controls in conditional mouse experiments: Mrp8-cre transgene predisposes mice to antibody-induced arthritis.

The Cre/loxP system is extensively utilized to pinpoint gene functions in specific cell types or developmental stages, typically without major disturbance to the host's genome. However, we found that the random insertion of the Mrp8-cre transgene significantly promotes the host's innate immune response. This effect is characterized by elevated susceptibility to cartilage antibody-induced arthritis, likely due to interference with genes near the insertion site.

Dynamics of the blood plasma proteome during hyperacute HIV-1 infection.

The complex dynamics of protein expression in plasma during hyperacute HIV-1 infection and its relation to acute retroviral syndrome, viral control, and disease progression are largely unknown. Here, we quantify 1293 blood plasma proteins from 157 longitudinally linked plasma samples collected before, during, and after hyperacute HIV-1 infection of 54 participants from four sub-Saharan African countries. Six distinct longitudinal expression profiles are identified, of which four demonstrate a consistent decrease in protein levels following HIV-1 infection.

has mammal-like mutation rates facilitating fast adaptation despite its nonaging phenotype.

Growing evidence suggests that somatic mutations may be a major cause of the aging process. However, it remains to be tested whether the predictions of the theory also apply to species with longer life spans than humans. is a genus of freshwater polyps with remarkable regeneration abilities and a potentially unlimited life span under laboratory conditions.

Multicamera simultaneous total internal reflection and interference reflection microscopy.

Interference Reflection Microscopy (IRM) is an optical technique that relies on the interference between the reflected light from an incident beam as it passes through materials of different refractive indices. This technique has been successfully used to image microtubules, biologically important biofilaments with a diameter of 25 nm. However, it is often desirable to image both the microtubule and microtubule interacting proteins simultaneously.

Implementation and validation of single-cell genomics experiments in neuroscience.

Single-cell or single-nucleus transcriptomics is a powerful tool for identifying cell types and cell states. However, hypotheses derived from these assays, including gene expression information, require validation, and their functional relevance needs to be established. The choice of validation depends on numerous factors.

Opportunities and challenges of single-cell and spatially resolved genomics methods for neuroscience discovery.

Over the past decade, single-cell genomics technologies have allowed scalable profiling of cell-type-specific features, which has substantially increased our ability to study cellular diversity and transcriptional programs in heterogeneous tissues. Yet our understanding of mechanisms of gene regulation or the rules that govern interactions between cell types is still limited. The advent of new computational pipelines and technologies, such as single-cell epigenomics and spatially resolved transcriptomics, has created opportunities to explore two new axes of biological variation: cell-intrinsic regulation of cell states and expression programs and interactions between cells.

Response and adaptation of the transcriptional heat shock response to pressure.

Introduction: The molecular mechanisms underlying pressure adaptation remain largely unexplored, despite their significance for understanding biological adaptation and improving sterilization methods in the food and beverage industry. The heat shock response leads to a global stabilization of the proteome. Prior research suggested that the heat shock regulon may exhibit a transcriptional response to high-pressure stress.

α/β Hydrolases: Toward Unraveling Entangled Classification.

α/β Hydrolase-like enzymes form a large and functionally diverse superfamily of proteins. Despite retaining a conserved structural core consisting of an eight-stranded, central β-sheet flanked with six α-helices, they display a modular architecture allowing them to perform a variety of functions, like esterases, lipases, peptidases, epoxidases, lyases, and others. At the same time, many α/β hydrolase-like families, even enzymatically distinct, share a high degree of sequence similarity.

Inborn errors of immunity reveal molecular requirements for generation and maintenance of human CD4 IL-9-expressing cells.

Background: CD4 T cells play essential roles in adaptive immunity. Distinct CD4 T-cell subsets-T1, T2, T17, T22, T follicular helper, and regulatory T cells-have been identified, and their contributions to host defense and immune regulation are increasingly well defined. IL-9-producing T9 cells were first described in 2008 and appear to play both protective and pathogenic roles in human immunity.

Dynamics and mechanism of DNA repair by a bifunctional cryptochrome.

Photolyase and cryptochrome belong to a group of structurally similar flavoproteins but with two distinct functions of DNA repair as a photoenzyme and signal transduction as a photoreceptor, respectively, under blue-light illumination. Here, we studied a recently discovered bifunctional cryptochrome (CraCRY) with focus on its repair of UV-induced pyrimidine-pyrimidone (6-4) photoproduct (6-4PP). We used femtosecond spectroscopy and site-directed mutagenesis to map out the critical elementary steps by following the dynamics of initial reactants, various intermediates, and final products.

Roles of SNORD115 and SNORD116 ncRNA clusters during neuronal differentiation.

In the snoRNA host gene SNHG14, 29 consecutive introns each generate SNORD116, and 48 tandem introns encode SNORD115. Loss of SNORD116 expression, but not of SNORD115, is linked to the neurodevelopmental disease Prader-Willi syndrome. SNORD116 and SNORD115 resemble box C/D small nucleolar RNAs (snoRNAs) but lack known targets.

Asymptomatic Hyperuricemia: A Nephro-Rheumatological Perspective.

Hyperuricemia (HU) is a common disorder associated with gout, kidney injury, and high cardiovascular risk. However, whether high serum uric acid (sUA) is a causative factor or just comorbidity remains unclear. When asked if asymptomatic hyperuricemic patients need treatment, even artificial intelligence in the form of the GPT chat provides an ambivalent answer and refers us to a healthcare provider.

Analysis of the quadruple lsu mutant reveals molecular determinants of the role of LSU proteins in sulfur assimilation in Arabidopsis.

Because plants are immobile, they have developed intricate mechanisms to sense and absorb nutrients, adjusting their growth and development accordingly. Sulfur is an essential macroelement, but our understanding of its metabolism and homeostasis is limited. LSU (RESPONSE TO LOW SULFUR) proteins are plant-specific proteins with unknown molecular functions and were first identified during transcriptomic studies on sulfur deficiency in Arabidopsis.

Tripartite interactions of PKA catalytic subunit and C-terminal domains of cardiac Ca channel may modulate its β-adrenergic regulation.

Background: The β-adrenergic augmentation of cardiac contraction, by increasing the conductivity of L-type voltage-gated Ca1.2 channels, is of great physiological and pathophysiological importance. Stimulation of β-adrenergic receptors (βAR) activates protein kinase A (PKA) through separation of regulatory (PKAR) from catalytic (PKAC) subunits.

Non-invasive in vivo sensing of bacterial implant infection using catalytically-optimised gold nanocluster-loaded liposomes for urinary readout.

Staphylococcus aureus is a leading cause of nosocomial implant-associated infections, causing significant morbidity and mortality, underscoring the need for rapid, non-invasive, and cost-effective diagnostics. Here, we optimise the synthesis of renal-clearable gold nanoclusters (AuNCs) for enhanced catalytic activity with the aim of developing a sensitive colourimetric diagnostic for bacterial infection. All-atom molecular dynamics (MD) simulations confirm the stability of glutathione-coated AuNCs and surface access for peroxidase-like activity in complex physiological environments.

Tetramerization of deoxyadenosine kinase meets the demands of a DNA replication substrate challenge in Giardia intestinalis.

The protozoan parasite Giardia intestinalis is one of only a few organisms lacking de novo synthesis of DNA building blocks (deoxyribonucleotides). Instead, the parasite relies exclusively on salvaging deoxyadenosine and other deoxyribonucleosides from its host environment. Here, we report that G.

CRISPRi-based screen of Autism Spectrum Disorder risk genes in microglia uncovers roles of in microglia endocytosis and synaptic pruning.

Autism Spectrum Disorders (ASD) are a set of neurodevelopmental disorders with complex biology. The identification of ASD risk genes from exome-wide association studies and de novo variation analyses has enabled mechanistic investigations into how ASD-risk genes alter development. Most functional genomics studies have focused on the role of these genes in neurons and neural progenitor cells.

A rare genetic variant in APEX1 is associated with familial amyotrophic lateral sclerosis with slow progression.

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disorder characterized by loss of motor neurons and progressive muscle weakness. We aimed to identify the pathogenic genetic variants in familial ALS (fALS) pedigrees and to elucidate their impact on the disease phenotype. Through the analysis of whole-genome sequencing data of 34 fALS probands that screened negative for mutations in the most common ALS-causing genes, we identified a rare missense variant in APEX1 (NM_001641.