SARS-CoV-2 infection of human lung epithelial cells induces TMPRSS-mediated acute fibrin deposition.

Severe COVID-associated lung injury is a major confounding factor of hospitalizations and death with no effective treatments. Here, we describe a non-classical fibrin clotting mechanism mediated by SARS-CoV-2 infected primary lung but not other susceptible epithelial cells. This infection-induced fibrin formation is observed in all variants of SARS-CoV-2 infections, and requires thrombin but is independent of tissue factor and other classical plasma coagulation factors. While prothrombin and fibrinogen levels are elevated in acute COVID BALF samples, fibrin clotting occurs only with the presence of viral infected but not uninfected lung epithelial cells. We suggest a viral-induced coagulation mechanism, in which prothrombin is activated by infection-induced transmembrane serine proteases, such as ST14 and TMPRSS11D, on NHBE cells. Our finding reveals the inefficiency of current plasma targeted anticoagulation therapy and suggests the need to develop a viral-induced ARDS animal model for treating respiratory airways with thrombin inhibitors.

FcγRI FG-loop functions as a pH sensitive switch for IgG binding and release.

Understanding the molecular mechanism underlying the hierarchic binding between FcγRs and IgG antibodies is critical for therapeutic antibody engineering and FcγR functions. The recent determination of crystal structures of FcγRI-Fc complexes, however, resulted in two controversial mechanisms for the high affinity receptor binding to IgG. Here, we describe high resolution structures of a bovine FG-loop variant of FcγRI in complex with the Fc fragment of IgG1 crystallized in three different conditions at neutral pH, confirming the characteristic FG loop-Fc interaction is critical to the high affinity immunoglobulin binding. We showed that the FcγRI D2-domain FG-loop functioned as a pH-sensing switch for IgG binding. Further live cell imaging of FcγRI-mediated internalization of immune complexes showed a pH sensitive temporal-spatial antibody-antigen uptake and release. Taken together, we demonstrate that the structures of FcγRI-Fc crystallized at neutral and acidic pH, respectively, represent the high and low affinity binding states of the receptor for IgG uptake and release. These results support a role for FcγRI in antigen delivery, highlight the importance of Fc glycan in antibody binding to the high affinity receptor and provide new insights to future antibody engineering.

HIV-1 release requires Nef-induced caspase activation.

HIV infection remains incurable to date and there are no compounds targeted at the viral release. We show here HIV viral release is not spontaneous, rather requires caspases activation and shedding of its adhesion receptor, CD62L. Blocking the caspases activation caused virion tethering by CD62L and the release of deficient viruses. Not only productive experimental HIV infections require caspases activation for viral release, HIV release from both viremic and aviremic patient-derived CD4 T cells also require caspase activation, suggesting HIV release from cellular viral reservoirs depends on apoptotic shedding of the adhesion receptor. Further transcriptomic analysis of HIV infected CD4 T cells showed a direct contribution of HIV accessory gene Nef to apoptotic caspases activation. Current HIV cure focuses on the elimination of latent cellular HIV reservoirs that are resistant to infection-induced cell death. This has led to therapeutic strategies to stimulate T cell apoptosis in a "kick and kill" approach. Our current work has shifted the paradigm on HIV-induced apoptosis and suggests such approach would risk to induce HIV release and thus be counter-productive. Instead, our study supports targeting of viral reservoir release by inhibiting of caspases activation.

Developing a secretory AcGFP1-based IRES expression system for efficient production of mammalian recombinant proteins.

To generate stable cell lines that express high levels of recombinant genes often requires screening of a large number of transfected cells using ELISA. The most widely used alternative to ELISA screening is to use an intracellularly expressed GFP reporter construct which allows sorting of recombinant gene expression cells based on GFP fluorescence intensity. The disadvantage of cell sorting, however, is that the resulting population will be polyclonal with the danger of instability and overgrowth of low producers. In addition, GFP or its variants can be toxic to host cells at high concentrations, and thus may reduce growth and robustness of high producer cells or even cause them to become apoptotic. We have developed a new mammalian expression system in which a recombinant protein and a fluorescence protein, AcGFP1, are expressed on the same plasmid separated by an internal ribosome entry site (IRES). A signal peptide was incorporated upstream of AcGFP1 so that the fluorescent protein is secreted from cells, preventing cellular toxicity from intracellular accumulation and enabling convenient and accurate measurement of the protein. Expression tests of Ebola viral envelope GP1 and HIV gp120 proteins using this expression system in 293-H cells showed recombinant protein expression levels were closely correlated with AcGFP1 yield. Therefore, AcGFP1 can serve as an accurate reporter for recombinant protein expression and measuring AcGFP1 concentration provides a convenient, product independent and universal way for efficient clone screening.

The Role of L-Selectin in HIV Infection.

HIV envelope glycoprotein is the most heavily glycosylated viral protein complex identified with over 20 glycans on its surface. This glycan canopy is thought to primarily shield the virus from host immune recognition as glycans are poor immunogens in general, however rare HIV neutralizing antibodies nevertheless potently recognize the glycan epitopes. While CD4 and chemokine receptors have been known as viral entry receptor and coreceptor, for many years the role of viral glycans in HIV entry was controversial. Recently, we showed that HIV envelope glycan binds to L-selectin in solution and on CD4 T lymphocytes. The viral glycan and L-selectin interaction functions to facilitate the viral adhesion and entry. Upon entry, infected CD4 T lymphocytes are stimulated to progressively shed L-selectin and suppressing this lectin receptor shedding greatly reduced HIV viral release and caused aggregation of diminutive virus-like particles within experimental infections and from infected primary T lymphocytes derived from both viremic and aviremic individuals. As shedding of L-selectin is mediated by ADAM metalloproteinases downstream of host-cell stimulation, these findings showed a novel mechanism for HIV viral release and offer a potential new class of anti-HIV compounds.

High level stable expression of recombinant HIV gp120 in glutamine synthetase gene deficient HEK293T cells.

Due to the important pathological roles of the HIV-1 gp120, the protein has been intensively used in the research of HIV. However, recombinant gp120 preparation has proven to be difficult because of extremely low expression levels. In order to facilitate gp120 expression, previous methods predominantly involved the replacement of native signal peptide with a heterologous one, resulting in very limited improvement. Currently, preparation of recombinant gp120 with native glycans relies solely on transient expression systems, which are not amendable for large scale production. In this work, we employed a different approach for gp120 expression. Besides replacing the native gp120 signal peptide with that of rat serum albumin and optimizing its codon usage, we generated a stable gp120-expressing cell line in a glutamine synthetase knockout HEK293T cell line that we established for the purpose of amplification of recombinant gene expressions. The combined usage of these techniques dramatically increased gp120 expression levels and yielded a functional product with human cell derived glycan. This method may be applicable to large scale preparation of other viral envelope proteins, such as that of the emerging SARS-CoV-2, or other glycoproteins which require the presence of authentic human glycans.

HIV-1 targets L-selectin for adhesion and induces its shedding for viral release.

CD4 and chemokine receptors mediate HIV-1 attachment and entry. They are, however, insufficient to explain the preferential viral infection of central memory T cells. Here, we identify L-selectin (CD62L) as a viral adhesion receptor on CD4+ T cells. The binding of viral envelope glycans to L-selectin facilitates HIV entry and infection, and L-selectin expression on central memory CD4+ T cells supports their preferential infection by HIV. Upon infection, the virus downregulates L-selectin expression through shedding, resulting in an apparent loss of central memory CD4+ T cells. Infected effector memory CD4+ T cells, however, remain competent in cytokine production. Surprisingly, inhibition of L-selectin shedding markedly reduces HIV-1 infection and suppresses viral release, suggesting that L-selectin shedding is required for HIV-1 release. These findings highlight a critical role for cell surface sheddase in HIV-1 pathogenesis and reveal new antiretroviral strategies based on small molecular inhibitors targeted at metalloproteinases for viral release.

Over-expression of a human CD62L ecto-domain and a potential role of RNA pseudoknot structures in recombinant protein expression.

L-selectin (CD62L) is an extracellular protein with a lectin-like domain that mediates rolling adhesion of leukocytes to vascular endothelial cell surfaces. Currently, there are no solved structures for the ectodomain of CD62L, nor of CD62L in complex with its ligand. We have developed a rapid mammalian recombinant protein expression system using an amplifiable glutamine synthase based vector. Here, we further developed and applied this method to express and purify the entire extracellular region of CD62L. This resulted in excess of 20 mg/L yield of recombinant CD62L. In an attempt to understand the different expression levels among four similar CD62L constructs that differ primarily in signal sequences, we calculated the presence of potential RNA pseudoknots in their signal sequences. The results showed the presence of pseudoknots involving the start codon and between the signal sequence and gene in the mRNA of the non-expressing constructs, suggesting a potential inhibitory role of RNA pseudoknots in recombinant protein expression.

Overexpression of Ebola virus envelope GP1 protein.

Ebola virus uses its envelope GP1 and GP2 for viral attachment and entry into host cells. Due to technical difficulty expressing full-length envelope, many structural and functional studies of Ebola envelope protein have been carried out primarily using GP1 lacking its mucin-like domain. As a result, the viral invasion mechanisms involving the mucin-like domain are not fully understood. To elucidate the role of the mucin-like domain of GP1 in Ebola-host attachment and infection and to facilitate vaccine development, we constructed a GP1 expression vector containing the entire attachment region (1-496). Cysteine 53 of GP1, which forms a disulfide bond with GP2, was mutated to serine to avoid potential disulfide bond mispairing. Stable expression clones using codon optimized open reading frame were developed in human 293-H cells with yields reaching ∼25 mg of GP1 protein per liter of spent medium. Purified GP1 was functional and bound to Ebola attachment receptors, DC-SIGN and DC-SIGNR. The over-expression and easy purification characteristic of this system has implications in Ebola research and vaccine development. To further understand the differential expression yields between the codon optimized and native GP1, we analyzed the presence of RNA structural motifs in the first 100 nucleotides of translational initiation AUG site. RNA structural prediction showed the codon optimization removed two potential RNA pseudoknot structures. This methodology is also applicable to the expression of other difficult virus envelope proteins.

[The Research on Reinspection Problems in Supervisory Sampling Inspection for Medical Devices].

Supervisory sampling inspection is one of the administrative supervision measures for medical devices. As the reinspection work affects the final conclusion of sampling inspection, inappropriate overturn during the reinspection has already impaired the impartiality and authority of the supervisory inspection work. By the statistics of survey materials, this article analyzes the reasons for requesting reinspection and making overturns, and proposes a scheme for eliminating the interference factors such as the understanding divergences and the defects of standards, the inspection capacity and the issues of sampled devices, etc. To enhance the authoritative of reinspection, this article also proposes principals of evasion, precedence, arbitration and assessment, and the improvement of the reinspection workflow in order to make the reinspection work more appropriate, more efficient and more impartial.

Structure of FcγRI in complex with Fc reveals the importance of glycan recognition for high-affinity IgG binding.

Fc gamma receptor I (FcγRI) contributes to protective immunity against bacterial infections, but exacerbates certain autoimmune diseases. The sole high-affinity IgG receptor, FcγRI plays a significant role in immunotherapy. To elucidate the molecular mechanism of its high-affinity IgG binding, we determined the crystal structure of the extracellular domains of human FcγRI in complex with the Fc domain of human IgG1. FcγRI binds to the Fc in a similar mode as the low-affinity FcγRII and FcγRIII receptors. In addition to many conserved contacts, FcγRI forms additional hydrogen bonds and salt bridges with the lower hinge region of Fc. Unique to the high-affinity receptor-Fc complex, however, is the conformation of the receptor D2 domain FG loop, which enables a charged KHR motif to interact with proximal carbohydrate units of the Fc glycans. Both the length and the charge of the FcγRI FG loop are well conserved among mammalian species. Ala and Glu mutations of the FG loop KHR residues showed significant contributions of His-174 and Arg-175 to antibody binding, and the loss of the FG loop-glycan interaction resulted in an ∼ 20- to 30-fold decrease in FcγRI affinity to all three subclasses of IgGs. Furthermore, deglycosylation of IgG1 resulted in a 40-fold loss in FcγRI binding, demonstrating involvement of the receptor FG loop in glycan recognition. These results highlight a unique glycan recognition in FcγRI function and open potential therapeutic avenues based on antibody glycan engineering or small molecular glycan mimics to target FcγRI for certain autoimmune diseases.

Development of an improved mammalian overexpression method for human CD62L.

We have previously developed a glutamine synthetase (GS)-based mammalian recombinant protein expression system that is capable of producing 5-30mg/L recombinant proteins. The over expression is based on multiple rounds of target gene amplification driven by methionine sulfoximine (MSX), an inhibitor of glutamine synthetase. However, like other stable mammalian over expression systems, a major shortcoming of the GS-based expression system is its lengthy turn-around time, typically taking 4-6months to produce. To shorten the construction time, we replaced the multi-round target gene amplifications with single-round in situ amplifications, thereby shortening the cell line construction to 2months. The single-round in situ amplification method resulted in highest recombinant CD62L expressing CHO cell lines producing ∼5mg/L soluble CD62L, similar to those derived from the multi-round amplification and selection method. In addition, we developed a MSX resistance assay as an alternative to utilizing ELISA for evaluating the expression level of stable recombinant CHO cell lines.

Natural killer cell-produced IFN-γ and TNF-α induce target cell cytolysis through up-regulation of ICAM-1.

NK cells control tumor and virus-infected cells through releasing cytotoxic granules and proinflammatory cytokines. IFN-γ and TNF-α secretions and cytotoxicity are regarded as two distinct functions of NK cells with little synergy in between as results of early association of the two functions with distinct subsets of NK populations and of the studies showing target cells developing NK resistance upon IFN-γ treatment. Here, we show that IFN-γ and TNF-α synergistically enhance NK cell cytotoxicity through NF-κB-dependent up-regulation of ICAM-1 expression in target cells, thereby promoting their conjugate formation with NK cells. Neutralizing IFN-γ and TNF-α during cytolysis significantly impaired NK cell lysis of the target cells. Further, tumor cells exhibiting IFN-γ-inducible lysis are generally less-sensitive NK target cells but express inducible levels of ICAM-1. In contrast, sensitive NK targets tend to express higher but less-inducible ICAM-1. Their preferential induction in the lysis of insensitive NK target cells suggests that IFN-γ and TNF-α are functionally linked to and should be regarded as an integral part of NK cytolytic function.

Siglecs facilitate HIV-1 infection of macrophages through adhesion with viral sialic acids.

BACKGROUND: Human immunodeficiency virus type 1 (HIV-1) infects macrophages effectively, despite relatively low levels of cell surface-expressed CD4. Although HIV-1 infections are defined by viral tropisms according to chemokine receptor usage (R5 and X4), variations in infection are common within both R5- and X4-tropic viruses, indicating additional factors may contribute to viral tropism. METHODOLOGY AND PRINCIPAL FINDINGS: Using both solution and cell surface binding experiments, we showed that R5- and X4-tropic HIV-1 gp120 proteins recognized a family of I-type lectin receptors, the Sialic acid-binding immunoglobulin-like lectins (Siglec). The recognition was through envelope-associated sialic acids that promoted viral adhesion to macrophages. The sialic acid-mediated viral-host interaction facilitated both R5-tropic pseudovirus and HIV-1(BaL) infection of macrophages. The high affinity Siglec-1 contributed the most to HIV-1 infection and the variation in Siglec-1 expression on primary macrophages from different donors was associated statistically with sialic acid-facilitated viral infection. Furthermore, envelope-associated sialoglycan variations on various strains of R5-tropic viruses also affected infection. CONCLUSIONS AND SIGNIFICANCE OF THE FINDINGS: Our study showed that sialic acids on the viral envelope facilitated HIV-1 infection of macrophages through interacting with Siglec receptors, and the expression of Siglec-1 correlated with viral sialic acid-mediated host attachment. This glycan-mediated viral adhesion underscores the importance of viral sialic acids in HIV infection and pathogenesis, and suggests a novel class of antiviral compounds targeting Siglec receptors.

Structural and functional studies of Igalphabeta and its assembly with the B cell antigen receptor.

The B cell antigen receptor (BCR) plays an essential role in all phases of B cell development. Here we show that the extracellular domains of murine and human Igbeta form an I-set immunoglobulin-like structure with an interchain disulfide between cysteines on their G strands. Structural and sequence analysis suggests that Igalpha displays a similar fold as Igbeta. An Igalphabeta heterodimer model was generated based on the unique disulfide-bonded Igbeta dimer. Solution binding studies showed that the extracellular domains of Igalphabeta preferentially recognize the constant region of BCR with mu chain specificity, suggesting a role for Igalphabeta to enhance BCRmu chain signaling. Cluster mutations on Igalpha, Igbeta, and a membrane-bound form of immunoglobulin (mIgM) based on the structural model identified distinct areas of potential contacts involving charged residues on both subunits of the coreceptor and the Cmu4 domain of mIgM. These studies provide the first structural model for understanding BCR function.

Influence of the second amino acid on recombinant protein expression.

Factors affecting protein expression have been intensely studied to the benefit of recombinant protein production. Through mutational analysis at the +2 amino acid position of recombinant Igα, we examined the effect of all 20 amino acids on protein expression. The results showed that amino acids at the +2 position affected 10-fold in the recombinant protein expression. Specifically, Ala, Cys, Pro, Ser, Thr, and Lys at the +2 position resulted in significantly higher expression of recombinant Igα than other amino acids, while Met, His and Glu resulted in greatly reduced protein expression. This expression difference depended on the amino acid instead of their codon usage. Consistent with the mutational results, a statistically significant enrichment in Ala and Ser at the +2 position was observed among highly expressed Escherichia coli genes. This work suggests a general approach to enhance protein expression by incorporating an Ala or Ser after the initiation codon.

Ternary complex of transforming growth factor-beta1 reveals isoform-specific ligand recognition and receptor recruitment in the superfamily.

Transforming growth factor (TGF)-beta1, -beta2, and -beta3 are 25-kDa homodimeric polypeptides that play crucial nonoverlapping roles in embryogenesis, tissue development, carcinogenesis, and immune regulation. Here we report the 3.0-A resolution crystal structure of the ternary complex between human TGF-beta1 and the extracellular domains of its type I and type II receptors, TbetaRI and TbetaRII. The TGF-beta1 ternary complex structure is similar to previously reported TGF-beta3 complex except with a 10 degrees rotation in TbetaRI docking orientation. Quantitative binding studies showed distinct kinetics between the receptors and the isoforms of TGF-beta. TbetaRI showed significant binding to TGF-beta2 and TGF-beta3 but not TGF-beta1, and the binding to all three isoforms of TGF-beta was enhanced considerably in the presence of TbetaRII. The preference of TGF-beta2 to TbetaRI suggests a variation in its receptor recruitment in vivo. Although TGF-beta1 and TGF-beta3 bind and assemble their ternary complexes in a similar manner, their structural differences together with differences in the affinities and kinetics of their receptor binding may underlie their unique biological activities. Structural comparisons revealed that the receptor-ligand pairing in the TGF-beta superfamily is dictated by unique insertions, deletions, and disulfide bonds rather than amino acid conservation at the interface. The binding mode of TbetaRII on TGF-beta is unique to TGF-betas, whereas that of type II receptor for bone morphogenetic protein on bone morphogenetic protein appears common to all other cytokines in the superfamily. Further, extensive hydrogen bonds and salt bridges are present at the high affinity cytokine-receptor interfaces, whereas hydrophobic interactions dominate the low affinity receptor-ligand interfaces.

An improved recombinant mammalian cell expression system for human transforming growth factor-beta2 and -beta3 preparations.

Transforming growth factor-beta2 and -beta3 (TGF-beta2 and -beta3) are important members of TGF-beta family which play important roles in the growth, maintenance, and repair processes of developing embryos, neonates, and adults. Preparation of large quantities of these two cytokines, which is necessary for structural studies and other applications, has proven to be extremely difficult. We have developed a novel Chinese hamster ovary cell-based expression system for high-level expression and high recovery of recombinant human TGF-beta2 and -beta3. In this system, we used a mammalian expression vector which contains a glutamine synthetase coding region for amplification, together with a modified TGF-beta2 or -beta3 open reading frame for expression. The leader peptide of TGF-beta2 or -beta3 was replaced by that from the V-J2-C region of a mouse immunoglobulin kappa-chain, and a poly-histidine tag was inserted immediately after the leader sequence to facilitate protein purification without changing the mature TGF-beta2 or -beta3 amino acid sequence. In addition, the extreme N-terminal cysteine residue of TGF-beta2 or -beta3 was replaced by a serine residue. The resulting expression constructs produced two stable cell clones expressing 10 mg of TGF-beta2 and 8 mg of TGF-beta3 per liter of spent medium. The purification scheme involved the use of two simple chromatographic steps with a typical yield of 5 mg of TGF-beta2 and 4 mg of TGF-beta3. This method represents a significant improvement over previously published methods and may be applicable to other TGF-beta superfamily members. We further confirmed that latent TGF-beta2 and -beta3 can be activated by proteolysis and glycolysis, which have not been reported before.

Overexpression of human transforming growth factor-beta1 using a recombinant CHO cell expression system.

Transforming growth factor-beta1 (TGF-beta1) is secreted by most cells as a high molecular weight latent complex, which consists of latent TGF-beta1 disulfide bonded to latent TGF-beta1-binding protein (LTBP). Current recombinant expression systems yield less than 1-2 mg of the mature TGF-beta1 per liter of cell culture medium. In an effort to produce large quantities of the recombinant cytokine for structural studies, we have constructed a mammalian expression system based on a modified pcDNA3.1(+) vector with a glutamine synthetase gene inserted for gene amplification. The leader peptide of TGF-beta1 was replaced with that of rat serum albumin, and an eight-histidine tag was inserted immediately after the leader sequence to facilitate protein purification. In addition, Cys 33 of TGF-beta1, which forms a disulfide bond with LTBP, was replaced by a serine residue. The resulting expression construct produced a stable clone expressing 30 mg of mature TGF-beta1 per liter of spent medium. Purified TGF-beta1 bound with high affinity to its type II receptor with a solution dissociation constant of approximately 70 nM, and was fully active in both a Mv1Lu cell growth inhibition assay and in a PAI-1 luciferase reporter assay. Owing to similarities in the synthesis, secretion, and structure of TGF-beta family members, this recombinant expression system may also be applied to the overexpression of other TGF-beta isomers and even to members of the TGF-beta superfamily to facilitate their preparation.

Making sense of the diverse ligand recognition by NKG2D.

NKG2D recognizes multiple diverse ligands. Despite recent efforts in determining the crystal structures of NKG2D-ligand complexes, the principle governing this receptor-ligand recognition and hence the criteria for identifying unknown ligands of NKG2D remain central issues to be resolved. Here we compared the molecular recognition between NKG2D and three of the known ligands, UL16 binding protein (ULBP), MHC class I-like molecule, and retinoic acid early inducible gene as observed in the ligand-complexed crystal structures. The comparison shows that while the receptor uses a common interface region to bind the three diverse ligands, each ligand forms a distinct, but overlapping, set of hydrogen bonds, hydrophobic interactions, and salt bridges, illustrating the underlying principle of NKG2D-ligand recognition being the conservation in overall shape complementarity and binding energy while permitting variation in ligand sequence through induced fit recognition. To further test this hypothesis and to distinguish between diverse recognition and promiscuous ligand binding, four ULBP3 interface mutations, H21A, E76A, R82M, and D169A, were generated to each disrupt a single hydrogen bond or salt bridge. All mutant ULBP3 displayed reduced receptor binding, suggesting a specific, rather than promiscuous, receptor-ligand recognition. Mutants with severe loss of binding affect the receptor interactions that are mostly buried. Finally, a receptor-ligand recognition algorithm was developed to assist the identification of diverse NKG2D ligands based on evaluating the potential hydrogen bonds, hydrophobic interactions, and salt bridges at the receptor-ligand interface.