Improved SARS-CoV-2 Spike Glycoproteins for Pseudotyping Lentiviral Vectors

The spike (S) glycoprotein of SARS-Cov-2 facilitates viral entry into target cells via the cell surface receptor angiotensin-converting enzyme 2 (ACE2). Third generation HIV-1 lentiviral vectors can be pseudotyped to replace the native CD4 tropic envelope protein of the virus and thereby either limit or expand the target cell population. We generated a modified S glycoprotein of SARS-Cov-2 to pseudotype lentiviral vectors which efficiently transduced ACE2-expressing cells with high specificity and contain minimal off-target transduction of ACE2 negative cells. By utilizing optimized codons, modifying the S cytoplasmic tail domain, and including a mutant form of the spike protein, we generated an expression plasmid encoding an optimized protein that produces S-pseudotyped lentiviral vectors at an infectious titer (TU/mL) 1000-fold higher than the unmodified S protein and 4 to 10-fold more specific than the widely used delta-19 S-pseudotyped lentiviral vectors. S-pseudotyped replication-defective lentiviral vectors eliminate the need for biosafety-level-3 laboratories required when developing therapeutics against SARS-CoV-2 with live infectious virus. Furthermore, S-pseudotyped vectors with high activity and specificity may be used as tools to understand the development of immunity against SARS-CoV-2, to develop assays of neutralizing antibodies and other agents that block viral binding, and to allow in vivo imaging studies of ACE2-expressing cells.

Robust maintenance of cell surface tension in mitosis by RhoA-driven myosin II mechanoresponse

As cells enter mitosis, cell cortex contraction generates surface tension to establish a geometry feasible for division in a physically confined environment. Cell surface tension rises in prophase and continues to stay constant during metaphase to support mitosis. How the cell surface tension is maintained throughout mitosis is not well explored. We show that the cell surface tension is actively maintained by a mechanosensitive RhoA pathway at the cell cortex during mitosis. Mechanical activation of RhoA leads to non-muscle myosin IIB (NMIIB) stabilization and mechanosensitive accumulation at the cell cortex via Rho kinase (ROCK) regulation of the NMIIB head domain. Interestingly, when the NMIIB tail domain regulation is perturbed, the NMIIB has reduced ability to generate tension but could still support mitotic cells to withstand compressive stress by undergoing mechanosensitive accumulation at the cell cortex. Thus, mechanical RhoA activation drives NMIIB mechanoresponse via its head domain regulation to maintain cell surface tension during mitosis.

Charged Domain Wall and Polar Vortex Topologies in a Room Temperature Magnetoelectric Multiferroic Thin Film

Multiferroic topologies are an emerging solution for future low-power magnetic nanoelectronics due to their combined tuneable functionality and mobility. Here, we show that in addition to being magnetoelectric multiferroic at room temperature, thin film Aurivillius phase Bi6TixFeyMnzO18 is an ideal material platform for both domain wall and vortex topology based nanoelectronic devices. Utilising atomic resolution electron microscopy, we reveal the presence and structure of 180˚ type charged head-to-head and tail-to-tail domain walls passing throughout the thin film. Theoretical calculations confirm the sub-unit cell cation site preference and charged domain wall energetics for Bi6TixFeyMnzO18. Finally, we show that polar vortex type topologies also form at out-of-phase boundaries of stacking faults when internal strain and electrostatic energy gradients are altered. This study could pave the way for controlled polar vortex topology formation via strain engineering in other multiferroic thin films. Moreover, these results confirm the sub-unit-cell topological features play an important role in controlling the charge and spin state of Aurivillius phase films and other multiferroic heterostructures.

Charged Domain Wall and Polar Vortex Topologiesin a Room Temperature Magnetoelectric Multiferroic Thin Film

Multiferroic domain walls are an emerging solution for future low-power nanoelectronics due to their combined tuneable functionality and mobility. Here we show that the magnetoelectric multiferroic Aurivillius phase Bi6TixFeyMnzO18 (B6TFMO) crystal is an ideal platform for domain wall-based nanoelectronic devices. The unit cell of B6TFMO is distinctive as it consists of a multiferroic layer between dielectric layers. We utilise atomic resolution scanning transmission electron microscopy and spectroscopy to map the sub-unit-cell polarisation in B6TFMO thin films. 180˚ charged head-to-head and tail-to-tail domain walls are found to pass through > 8 ferroelectric-dielectric layers of the film. They are structurally similar to BiFeO3 DWs but contain a large surface charge density (σ_s) = 1.09 |e|per perovskite cell, where |e| is elementary charge. Although polarisation is primarily in-plane, c-axis polarisation is identified at head-to-tail domain walls with an associated electromechanical coupling of strain and polarisation. Finally, we reveal that with controlled strain engineering during thin film growth, room-temperature vortexes are formed in the ferroelectric layer. These results confirm that sub-unit-cell topological features can play an important role in controlling the conduction properties and magnetisation state of Aurivillius phase films and other multiferroic heterostructures.

Abstract P417: Cardiomyopathy-associated Variant In Troponin T Tail Domain Promotes Disruption Of Both Frank-starling Mechanism And Cardiac Myofilament Performance

Missense variant Ile79Asn in human cardiac troponin T (HcTnT-I79N) tail region has been linked to familial hypertrophic cardiomyopathy (HCM), arrhythmia, and sudden cardiac death. It has been reported that inotropic stimulation with high extracellular Ca 2+ or isoproterenol led to diastolic dysfunction in both isolated and in vivo HcTnT-I79N mice hearts. Although HcTnT-I79N effects are acknowledged to be dependent on the inotropic state of the cardiac muscle, little is known about how this pathogenic variant affects the Frank-Starling law of the heart. To further investigate the functional and structural consequences of this deadly variant in a stretch-dependent manner, cardiac tissues were harvested from non-transgenic (NTg) control mice and transgenic mice bearing HcTnT-I79N. Left ventricular papillary muscle bundles were permeabilized and mounted for mechanical measurements. Sarcomere length (SL 1.9, 2.1 or 2.3 μm) was set at pCa 8 using HeNe laser diffraction and then Ca 2+ -dependence of isometric force, sinusoidal stiffness (SS, 0.2% PTP length oscillation) and rate of tension redevelopment ( k TR ) were measured. We observed that HcTnT-I79N tissue exhibited increased myofilament Ca 2+ -sensitivity of force, increased SS, slower k TR at all levels of Ca 2+ -activation, and diminished length-dependent activation (LDA). Small-angle X-ray diffraction revealed that HcTnT-I79N permeabilized cardiac muscles exhibit smaller myofilament lattice spacing at longer SLs (2.1 μm and 2.3 μm) compared to NTg. Using 3% Dextran T500 to osmotically compress the myofilament lattice (SL 2.1 μm), HcTnT-I79N showed no change in myofilament lattice spacing and little change in contractile indices associated with LDA. Interestingly, upon osmotic compression, HcTnT-I79N displayed a decrease in disordered relaxed state (DRX, ON state) of myosin and an increase in super-relaxed state (SRX, OFF state) of myosin. We conclude that altered cardiac myofilament performance, lack of responsiveness to osmotic compression, and reduced LDA observed with HcTnT-I79N are partially due to a combination of smaller myofilament lattice and disturbed ON and OFF states of myosin.

Abstract P421: Analysis Of The Functional Relevance Of Human Beta-myosin Heavy Chain Post-translational Modifications

Sarcomeric proteins have been shown to be a target of post-translational modifications (PTMs). Phosphorylation and acetylation of several sarcomeric proteins have been reported to be important for fine-tuning of myocardial contractility. Given the emerging importance of understanding the potential role of PTMs on cardiac muscle performance in healthy and diseased states, we sought to identify novel PTMs on human cardiac beta-myosin heavy chain (beta-MHC). We found several high confidence beta-MHC peptides modified by K-acetylation and S- and T-phosphorylation found in non-diseased, ischemic, and non-ischemic human heart samples. Using bottom-up proteomics and label-free quantification, we identified seven high-confidence peptides (K34, K58, S210, T215, K429, K951, K1195) with K951 displaying significant reduction in acetylation levels in both ischemic and non-ischemic failing hearts compared to donor hearts. Molecular dynamics simulations were performed to better understand the functional significance of the beta-MHC PTMs. Focus was placed on modifications in the regions with greatest potential functional significance as well as modified residues with significantly altered abundance in diseased states (K951-Ac at the myosin tail nearby a binding site for myosin heads in the super-relaxed state). K951 is located in the myosin tail (S2) at the C-terminal end of simulated structure. In both unmodified and modified simulations, the tail fragment showed significant flexibility and partial unfolding at the C-terminus. In the unmodified simulations, the inter- and intra-helical contacts were maintained. However, when beta-MHC is acetylated at residue 951, these helical contacts were altered as the uncharged acetylated residue no longer formed strong hydrogen bonds with a residue of the opposite chain. This facilitated changes increase in inter-helical contacts, an increase in inter-helical distance, and disruption of the coiled-coil tail domain structure. Our study suggests that there are distinct differences in beta-MHC acetylation levels that appear to be influenced more by location of the modified residues than the type of heart disease (ischemic- and non-ischemic heart failure). Additionally, we speculate that these PTMs have the potential to modulate the interactions between beta-MHC and other regulatory sarcomeric proteins, as well as ADP-release rate of myosin, flexibility of S2 fragment, and cardiac myofilament contractility under normal and heart failure condition.

Autoregulation and Dual Stepping Mode of MYA2, an Arabidopsis Myosin XI Responsible for Cytoplasmic Streaming

Arabidopsis thaliana has 13 genes belonging to the myosin XI family. Myosin XI-2 (MYA2) plays a major role in the generation of cytoplasmic streaming in cells. In this study, we investigated the molecular properties of MYA2 expressed by the baculovirus transfer system. Actin-activated ATPase activity and in vitro motility assays revealed that activity of MYA2 was regulated by the globular tail domain (GTD), When the GTD is not bound to the cargo, the GTD inhibits ADP dissociation from the motor domain. Optical nanometry of single MYA2 molecules, combining TIRF microscopy and the FIONA method, revealed that the MYA2 processively moved on actin with three different step sizes: −28 nm, 29 nm, and 60 nm, at low ATP concentrations. This result indicates that MYA2 uses two different stepping modes, hand-over-hand and inchworm-like. Force measurement using optical trapping showed the stall force of MYA2 was 0.85 pN, which was less than half that of myosin V (2 − 3 pN). These results indicated that MYA2 is more flexible than the myosin V responsible for vesicle transport in animal cells. Such flexibility may enable multiple myosin XIs to transport organelles quickly and smoothly, for the generation of cytoplasmic streaming in plant cells.

Generation and Evaluation of Recombinant Thermostable Newcastle Disease Virus Expressing the HA of H9N2 Avian Influenza Virus

H9N2 avian influenza virus (AIV) has become endemic in many countries, causing great economic losses when co-infected with other pathogens. So far, several live vaccines based on Newcastle disease virus (NDV) vectors expressing influenza hemagglutinin (HA) have been developed. However, the thermostable recombinant NDV is rarely reported. In this study, using a thermostable NDV rAHR09 strain as the vector, three recombinant NDVs expressing native HA, chimeric HA ectodomain with transmembrane domain/C-terminal cytoplasmic tail domain from fusion protein of NDV, and HA ectodomain were generated, designated rAHR09-HA, rAHR09-HAF, and rAHR09-HAE. The MDT value of three recombinant NDVs was above 120 h, their ICPI value was about 0.03, and the recombinant NDVs were still infectious when treated for 100 min under 56 °C, which demonstrated that the recombinant NDVs kept the lentogenic and thermostable nature of rAHR09. The immunization data showed that rAHR09-HA and rAHR09-HAF induced a higher HI antibody titer against H9N2 AIV and NDV. After being challenged with H9N2 AIV, the rAHR09-HA and rAHR09-HAF could significantly reduce the virus shedding in cloacal and tracheal swab samples. Our results suggest that rAHR09-HA and rAHR09-HAF might be vaccine candidates against H9N2 AIV.

Effect of Kinesin-5 Tail Domain on Motor Dynamics for Antiparallel Microtubule Sliding

Kinesin-5 motor consists of two pairs of heads and tail domains, which are situated at the opposite ends of a common stalk. The two pairs of heads can bind to two antiparallel microtubules (MTs) and move on the two MTs independently towards the plus ends, sliding apart the two MTs, which is responsible for chromosome segregation during mitosis. Prior experimental data showed that the tails of kinesin-5 Eg5 can modulate the dynamics of single motors and are critical for multiple motors to generate high steady forces to slide apart two antiparallel MTs. To understand the molecular mechanism of the tails modulating the ability of Eg5 motors, based on our proposed model the dynamics of the single Eg5 with the tails and that without the tails moving on single MTs is studied analytically and compared. Furthermore, the dynamics of antiparallel MT sliding by multiple Eg5 motors with the tails and that without the tails is studied numerically and compared. Both the analytical results for single motors and the numerical results for multiple motors are consistent with the available experimental data.