Efficient Degradation of Alginate And Preparation of Unsaturated Monosaccharides By A Novel Alginate Lyase And Effects of Domain Truncation On Biochemical Characteristics, Degradation Patterns

BackgroundBrown algae are considered promising crops for the production of sustainable biofuels. However, its commercial application has been limited by lack of efficient methods for converting alginate into fermentable sugars. Recently, exo-type alginate lyases have received extensive attention due to their excellent ability of conversion of alginate into 4-deoxy-L-erythro-5-hexoseulose uronate (DEH), a promising material for bioethanol production and biorefinery systems.ResultsHerein, we cloned and characterized a novel alginate lyase AlyPL17 from Pedobacter hainanensis NJ-02. It possessed outstanding catalytic efficiency towards polymannuronic acid (polyM), polyguluronic acid (polyG) and alginate sodium, with kcat of 39.42 + 1.9 s-1, 32.53 + 0.88 s-1, and 38.30 + 2.12 s-1, respectively. In addition, AlyPL17 adopts a unique hybrid action mode to degrade alginate by the synergistic effect of two domains. Furthermore, the combination of AlyPL17 and AlyPL6 exhibited apparently synergistic effect for the preparation of unsaturated monosaccharides. ConclusionOverall, the results show that AlyPL17 is a PL17 exo-type alginate lyase with high activity and a high conversion rate at low/moderate temperatures, which provides a useful enzymatic tool for the conversion of brown algae into biofuels and enhance our understanding of the function of modular domain of alginate lyase.

Molecular analyses identifies new domains and structural differences among Streptococcus pneumoniae immune evasion proteins PspC and Hic

The PspC and Hic proteins of Streptococcuspneumoniae are some of the most variable microbial immune evasion proteins identified to date. Due to structural similarities and conserved binding profiles, it was assumed for a long time that these pneumococcal surface proteins represent a protein family comprised of eleven subgroups. Recently, however, the evaluation of more proteins revealed a greater diversity of individual proteins. In contrast to previous assumptions a pattern evaluation of six PspC and five Hic variants, each representing one of the previously defined subgroups, revealed distinct structural and likely functionally regions of the proteins, and identified nine new domains and new domain alternates. Several domains are unique to PspC and Hic variants, while other domains are also present in other virulence factors encoded by pneumococci and other bacterial pathogens. This knowledge improved pattern evaluation at the level of full-length proteins, allowed a sequence comparison at the domain level and identified domains with a modular composition. This novel strategy increased understanding of individual proteins variability and modular domain composition, enabled a structural and functional characterization at the domain level and furthermore revealed substantial structural differences between PspC and Hic proteins. Given the exceptional genomic diversity of the multifunctional PspC and Hic proteins a detailed structural and functional evaluation need to be performed at the strain level. Such knowledge will also be useful for molecular strain typing and characterizing PspC and Hic proteins from new clinical S. pneumoniae strains.

The Conformational Plasticity Vista of PDZ Domains

The PDZ domain (PSD95-Discs large-ZO1) is a widespread modular domain present in the living organisms. A prevalent function in the PDZ family is to serve as scaffolding and adaptor proteins connecting multiple partners in signaling pathways. An explanation of the flexible functionality in this domain family, based just on a static perspective of the structure–activity relationship, might fall short. More dynamic and conformational aspects in the protein fold can be the reasons for such functionality. Folding studies indeed showed an ample and malleable folding landscape for PDZ domains where multiple intermediate states were experimentally detected. Allosteric phenomena that resemble energetic coupling between residues have also been found in PDZ domains. Additionally, several PDZ domains are modulated by post-translational modifications, which introduce conformational switches that affect binding. Altogether, the ability to connect diverse partners might arise from the intrinsic plasticity of the PDZ fold.

A Matter of Perspective: How adults represent causal launching sequences

The ability to reason about causal events in the world is fundamental to cognition. Despite the importance of this ability, little is known about how adults represent causal events, what structure or form those representations take, and what the mechanism is that underpins such representations. We report four experiments with adults that examine the perceptual basis on which adults represent four-object launching sequences (Experiments 1 and 2), whether adults representations reflect sensitivity to the causal, perceptual, or causal and perceptual relation among the objects that comprise such sequences (Experiment 3), and whether such representations extend beyond spatiotemporal contiguity to include other low-level stimulus features such as an object’s shape and color (Experiment 4). Based on these results of the four experiments, we argue that a domain-general associative mechanism, rather a modular, domain-specific, mechanism subserves adults’ representations of four-object launching sequences.

2.7 Å cryo-EM structure of rotavirus core protein VP3, a unique capping machine with a helicase activity

In many viruses, including rotavirus (RV), the major pathogen of infantile gastroenteritis, capping of viral messenger RNAs is a pivotal step for efficient translation of the viral genome. In RV, VP3 caps the nascent transcripts synthesized from the genomic dsRNA segments by the RV polymerase VP1 within the particle core. Here, from cryo–electron microscopy, x-ray crystallography, and biochemical analyses, we show that VP3 forms a stable tetrameric assembly with each subunit having a modular domain organization, which uniquely integrates five distinct enzymatic steps required for capping the transcripts. In addition to the previously known guanylyl- and methyltransferase activities, we show that VP3 exhibits hitherto unsuspected RNA triphosphatase activity necessary for initiating transcript capping and RNA helicase activity likely required for separating the RNA duplex formed transiently during endogenous transcription. From our studies, we propose a new mechanism for how VP3 inside the virion core caps the nascent transcripts exiting from the polymerase.

TASOR is a pseudo-PARP that directs HUSH complex assembly and epigenetic transposon control

SummaryThe Human Silencing Hub (HUSH) complex epigenetically represses retroviruses, transposons and genes in vertebrates. HUSH therefore maintains genome integrity and is central in the interplay between intrinsic immunity, transposable elements and transcriptional regulation. Comprising three subunits – TASOR, MPP8 and Periphilin – HUSH regulates SETDB1-dependent deposition of the transcriptionally repressive epigenetic mark H3K9me3 and recruits MORC2 to modify local chromatin structure. However the mechanistic roles of each HUSH subunit remain undetermined. Here we show that TASOR lies at the heart of HUSH, providing a platform for assembling the other subunits. Targeted epigenomic profiling supports the model that TASOR binds and regulates H3K9me3 specifically over LINE-1 repeats and other repetitive exons in transcribed genes. We find TASOR associates with several components of the nuclear RNA processing machinery and its modular domain architecture bears striking similarities to that of Chp1, the central component of the yeast RNA-induced transcriptional silencing (RITS) complex. Together these observations suggest that an RNA intermediate may be important for HUSH activity. We identify the TASOR domains necessary for HUSH assembly and transgene repression. Structural and genomic analyses reveal that TASOR contains a poly-ADP ribose polymerase (PARP) domain dispensable for assembly and chromatin localization, but critical for epigenetic regulation of target elements. This domain contains a degenerated and obstructed active site and has hence lost catalytic activity. Together our data demonstrate that TASOR is a pseudo-PARP critical for HUSH complex assembly and H3K9me3 deposition over its genomic targets.

Dynalogo: an interactive sequence logo with dynamic thresholding of matched quantitative proteomic data

Summary Current web-based sequence logo analyses for studying domain–peptide interactions are often conducted only on high affinity binders due to conservative data thresholding. We have developed Dynalogo, a combination of threshold varying tool and sequence logo generator written in the R statistical programming language, which allows on-the-fly visualization of binding specificity over a wide range of affinity interactions. Hence researchers can easily explore their dataset without the constraint of an arbitrary threshold. After importing quantitative data files, there are various data filtering and visualizing features available. Using a threshold control, users can easily track the dynamic change of enrichment and depletion of amino acid characters in the sequence logo panel. The built-in export function allows downloading filtered data and graphical outputs for further analyses. Dynalogo is optimized for analysis of modular domain–peptide binding experiments but the platform offers a broader application including quantitative proteomics. Availability and implementation Dynalogo application, user manual and sample data files are available at https://dynalogo.cam.uchc.edu. The source code is available at https://github.com/lafontaine-uchc/dynalogo. Supplementary information Supplementary data are available at Bioinformatics online.

Structure and functions of His domain protein tyrosine phosphatase in receptor trafficking and cancer

Cell surface receptors trigger the activation of signaling pathways to regulate key cellular processes, including cell survival and proliferation. Internalization, sorting, and trafficking of activated receptors, therefore, play a major role in the regulation and attenuation of cell signaling. Efficient sorting of endocytosed receptors is performed by the ESCRT machinery, which targets receptors for degradation by the sequential establishment of protein complexes. These events are tightly regulated and malfunction of ESCRT components can lead to abnormal trafficking and sustained signaling and promote tumor formation or progression. In this review, we analyze the modular domain organization of the alternative ESCRT protein HD-PTP and its role in receptor trafficking and tumorigenesis.