An analysis of LysM domain function in LytE when fulfilling the D,L-endopeptidase requirement for viability in Bacillus subtilis

The D,L-endopeptidase requirement states that Bacillus subtilis requires either the activity of the LytE or the CwlO enzyme for viability, therefore proving that these two enzymes can complement for each other despite their very different N-terminal domains. Here, we show that another D,L-endopeptidase, LytF, can also fulfill the D,L-endopeptidase requirement for viability, when expressed from the cwlO promoter. Both LytE and LytF contain N-terminally located LysM domains, three and five respectively. However, cells expressing another very similar D,L-endopeptidase CwlS, with four LysM domains were not viable. This led us to investigate whether a LytE protein with any one of its three LysM domains permuted can fulfill the D,L-endopeptidase requirement for viability. We found that the three LysM domains are not functionally equivalent and that the N-terminally located LysM domain plays a greater role for functioning of the LytE enzyme than the subsequent domains. Based on an investigation of orthologous enzymes in 19 B. subtilis species we propose an evolutionary model describing the development of the LytE-, CwlS- and LytF-type D,L-endopeptidases and their LysM domain repeats. In summary, these results show that the LytE enzyme has been optimized to fulfill the D,L-endopeptidase requirement for cell viability of B. subtilis with regard to the number and properties of LysM domains that mediate peptidoglycan-binding.

Structure of the bacterial flagellar hook cap provides insights into a hook assembly mechanism

Assembly of bacterial flagellar hook requires FlgD, a protein known to form the hook cap. Symmetry mismatch between the hook and the hook cap is believed to drive efficient assembly of the hook in a way similar to the filament cap helping filament assembly. However, the hook cap dependent mechanism of hook assembly has remained poorly understood. Here, we report the crystal structure of the hook cap composed of five subunits of FlgD from Salmonella enterica at 3.3 Å resolution. The pentameric structure of the hook cap is divided into two parts: a stalk region composed of five N-terminal domains; and a petal region containing five C-terminal domains. Biochemical and genetic analyses show that the N-terminal domains of the hook cap is essential for the hook-capping function, and the structure now clearly reveals why. A plausible hook assembly mechanism promoted by the hook cap is proposed based on the structure.

Nuclear restriction of HIV-1 infection by SUN1

Overexpression of the human Sad-1-Unc-84 homology protein 2 (SUN2) blocks HIV-1 infection in a capsid-dependent manner. In agreement, we showed that overexpression of SUN1 (Sad1 and UNC-84a) also blocks HIV-1 infection in a capsid-dependent manner. SUN2 and the related protein SUN1 are transmembrane proteins located in the inner membrane of the nuclear envelope. The N-terminal domains of SUN1/2 localizes to the nucleoplasm while the C-terminal domains are localized in the nuclear lamina. Because the N-terminal domains of SUN1/2 are located in the nucleoplasm, we hypothesized that SUN1/2 might be interacting with the HIV-1 replication complex in the nucleus leading to HIV-1 inhibition. Our results demonstrated that SUN1/2 interacts with the HIV-1 capsid, and in agreement with our hypothesis, the use of N-terminal deletion mutants showed that SUN1/2 proteins bind to the viral capsid by using its N-terminal domain. SUN1/2 deletion mutants correlated restriction of HIV-1 with capsid binding. Interestingly, the ability of SUN1/2 to restrict HIV-1 also correlated with perinuclear localization of these proteins. In agreement with the notion that SUN proteins interact with the HIV-1 capsid in the nucleus, we found that restriction of HIV-1 by overexpression of SUN proteins do not block the entry of the HIV-1 core into the nucleus. Our results showed that HIV-1 restriction is mediated by the interaction of SUN1/2N-terminal domains with the HIV-1 core in the nuclear compartment.

Structural and functional analysis of the C-terminal region of Streptococcus gordonii SspB

Streptococcus gordonii is a member of the viridans streptococci and is an early colonizer of the tooth surface. Adherence to the tooth surface is enabled by proteins present on the S. gordonii cell surface, among which SspB belongs to one of the most well studied cell-wall-anchored adhesin families: the antigen I/II (AgI/II) family. The C-terminal region of SspB consists of three tandemly connected individual domains that display the DEv-IgG fold. These C-terminal domains contain a conserved Ca2+-binding site and isopeptide bonds, and they adhere to glycoprotein 340 (Gp340; also known as salivary agglutinin, SAG). Here, the structural and functional characterization of the C123 SspB domain at 2.7 Å resolution is reported. Although the individual C-terminal domains of Streptococcus mutans AgI/II and S. gordonii SspB show a high degree of both sequence and structural homology, superposition of these structures highlights substantial differences in their electrostatic surface plots, and this can be attributed to the relative orientation of the individual domains (C1, C2 and C3) with respect to each other and could reflect their specificity in binding to extracellular matrix molecules. Studies further confirmed that affinity for Gp340 or its scavenger receptor cysteine-rich (SRCR) domains requires two of the three domains of C123 SspB, namely C12 or C23, which is different from AgI/II. Using protein–protein docking studies, models for this observed functional difference between C123 SspB and C123 AgI/II in their binding to SRCR1 are presented.

Characterization of a Knock-In Mouse Model with a Huntingtin Exon 1 Deletion

Background: The Huntingtin (HTT) N-terminal domains encoded by Huntingtin’s (HTT) exon 1 consist of an N17 domain, the polyglutamine (polyQ) stretch and a proline-rich region (PRR). These domains are conserved in mammals and have been hypothesized to modulate HTT’s functions in the developing and adult CNS, including DNA damage repair and autophagy. Objective: This study longitudinally characterizes the in vivo consequences of deleting the murine Htt N-terminal domains encoded by Htt exon 1. Methods: Knock-in mice with a deletion of Htt exon 1 sequences (Htt ΔE1) were generated and bred into the C57BL/6J congenic genetic background. Their behavior, DNA damage response, basal autophagy, and glutamatergic synapse numbers were evaluated. Results: Progeny from Htt ΔE1/+ intercrosses are born at the expected Mendelian frequency but with a distorted male to female ratio in both the Htt ΔE1/ΔE1 and Htt +/+ offspring. Htt ΔE1/ΔE1 adults exhibit a modest deficit in accelerating rotarod performance, and an earlier increase in cortical and striatal DNA damage with elevated neuronal pan-nuclear 53bp1 levels compared to Htt +/+ mice. However, a normal response to induced DNA damage, normal levels of basal autophagy markers, and no significant differences in corticocortical, corticostriatal, thalamocortical, or thalamostriatal synapses numbers were observed compared to controls. Conclusion: Our results suggest that deletion of the Htt N-terminus encoded by the Htt exon 1 does not affect Htt’s critical role during embryogenesis, but instead, may have a modest effect on certain motor tasks, basal levels of DNA damage in the brain, and Htt function in the testis.

Egg Case Protein 3: A Constituent of Black Widow Spider Tubuliform Silk

Spider silk has outstanding mechanical properties, rivaling some of the best materials on the planet. Biochemical analyses of tubuliform silk have led to the identification of TuSp1, egg case protein 1, and egg case protein 2. TuSp1 belongs to the spidroin superfamily, containing a non-repetitive N- and C-terminal domain and internal block repeats. ECP1 and ECP2, which lack internal block repeats and sequence similarities to the highly conserved N- and C-terminal domains of spidroins, have cysteine-rich N-terminal domains. In this study, we performed an in-depth proteomic analysis of tubuliform glands, spinning dope, and egg sacs, which led to the identification of a novel molecular constituent of black widow tubuliform silk, referred to as egg case protein 3 or ECP3. Analysis of the translated ECP3 cDNA predicts a low molecular weight protein of 11.8 kDa. Real-time reverse transcription–quantitative PCR analysis performed with different silk-producing glands revealed ECP3 mRNA is predominantly expressed within tubuliform glands of spiders. Taken together, these findings reveal a novel protein that is secreted into black widow spider tubuliform silk.

Dynamics of SARS-CoV-2 Spike Proteins in Cell Entry: Control Elements in the Amino-Terminal Domains

Adaptive changes that increase SARS-CoV-2 transmissibility may expand and prolong the coronavirus disease 2019 (COVID-19) pandemic. Transmission requires metastable and dynamic spike proteins that bind viruses to cells and catalyze virus-cell membrane fusion.

Refining the domain architecture model of the replication origin firing factor Treslin/TICRR

Faithful genome duplication requires appropriately controlled replication origin firing. The metazoan Treslin/TICRR origin firing factor and its yeast orthologue Sld3 are regulation hubs of origin firing. They share the Sld3-Treslin domain (STD) and the adjacent TopBP1/Dpb11 interaction domain (TDIN). We report a revised domain architecture model of Treslin/TICRR. Complementary protein sequence analyses uncovered Ku70-homologous lower case Greek beta-barrel folds in the Treslin/TICRR middle domain (M domain) and in Sld3. Thus, the Sld3-homologous Treslin/TICRR core comprises its three central domains, M domain, STD and TDIN. This Sld3-core is flanked by non-conserved terminal domains, the CIT (conserved in Treslins) and the C-terminus. We also identified Ku70-like lower case Greek beta-barrels in MTBP and Sld7. Our binding experiments showed that the Treslin lower case Greek beta-barrel mediates interaction with the MTBP lower case Greek beta-barrel, reminiscent of the homotypic Ku70-Ku80 dimerization. This binding mode is conserved in the Sld3-Sld7 dimer. We used Treslin/TICRR domain mutants to show that all Sld3-core domains and the non-conserved terminal domains fulfil important functions during origin firing in human cells. Thus, metazoa-specific and widely conserved molecular processes cooperate during origin firing in metazoa.

Regulation of Mitochondrial Respiration by VDAC Is Enhanced by Membrane-Bound Inhibitors with Disordered Polyanionic C-Terminal Domains

The voltage-dependent anion channel (VDAC) is the primary regulating pathway of water-soluble metabolites and ions across the mitochondrial outer membrane. When reconstituted into lipid membranes, VDAC responds to sufficiently large transmembrane potentials by transitioning to gated states in which ATP/ADP flux is reduced and calcium flux is increased. Two otherwise unrelated cytosolic proteins, tubulin, and α-synuclein (αSyn), dock with VDAC by a novel mechanism in which the transmembrane potential draws their disordered, polyanionic C-terminal domains into and through the VDAC channel, thus physically blocking the pore. For both tubulin and αSyn, the blocked state is observed at much lower transmembrane potentials than VDAC gated states, such that in the presence of these cytosolic docking proteins, VDAC’s sensitivity to transmembrane potential is dramatically increased. Remarkably, the features of the VDAC gated states relevant for bioenergetics—reduced metabolite flux and increased calcium flux—are preserved in the blocked state induced by either docking protein. The ability of tubulin and αSyn to modulate mitochondrial potential and ATP production in vivo is now supported by many studies. The common physical origin of the interactions of both tubulin and αSyn with VDAC leads to a general model of a VDAC inhibitor, facilitates predictions of the effect of post-translational modifications of known inhibitors, and points the way toward the development of novel therapeutics targeting VDAC.