Debulking different Corona (SARS-COV-2 delta, omicron, OC43) and influenza (H1N1, H3N2) virus strains by plant viral trap proteins in chewing gums to decrease infection and transmission

Because oral transmission of SARS-CoV-2 is 3–5 orders of magnitude higher than nasal transmission, we investigated debulking of oral viruses using viral trap proteins (CTB-ACE2, FRIL) expressed in plant cells, delivered through the chewing gum. In omicron nasopharyngeal (NP) samples, the microbubble count (based on N-antigen) was significantly reduced by 20 μg of FRIL (p < 0.0001) and 0.925 μg of CTB-ACE2 (p = 0.0001). Among 20 delta or omicron NP samples, 17 had virus load reduced below the detection level of spike protein in the RAPID assay, after incubation with the CTB-ACE2 gum powder. A dose-dependent 50% plaque reduction with 50–100 ng FRIL or 600–800 μg FRIL gum against Influenza strains H1N1, H3N2, and Coronavirus HCoV-OC43 was observed with both purified FRIL, lablab bean powder or gum. In electron micrographs, large/densely packed clumps of overlapping influenza particles and FRIL protein were observed. Chewing simulator studies revealed that CTB-ACE2 release was time/dose-dependent and release was linear up to 20 min chewing. Phase I/II placebo-controlled, double-blinded clinical trial (IND 154897) is in progress to evaluate viral load in saliva before or after chewing CTB-ACE2/placebo gum. Collectively, this study advances the concept of chewing gum to deliver proteins to debulk oral viruses and decrease infection/transmission.

Genetic and phenotypic characteristics of Clostridium (Clostridioides) difficile from canine, bovine, and pediatric populations

Objectives:

Carriage of Clostridioides difficile by different species of animals has led to speculation that animals could represent a reservoir of this pathogen for human infections. The objective of this study was to compare C. difficile isolates from humans, dogs, and cattle from a restricted geographic area.

Methods:

C. difficile isolates from 36 dogs and 15 dairy calves underwent whole genome sequencing, and phenotypic assays assessing growth and virulence were performed. Genomes of animal-derived isolates were compared to 29 genomes of isolates from a pediatric population as well as 44 reference genomes.

Results:

Growth rates and relative cytotoxicity of isolates were significantly higher and lower, respectively, in bovine-derived isolates compared to pediatric- and canine-derived isolates. Analysis of core genes showed clustering by host species, though in a few cases, human strains co-clustered with canine or bovine strains, suggesting possible interspecies transmission. Geographic differences (e.g., farm, litter) were small compared to differences between species. In an analysis of accessory genes, the total number of genes in each genome varied between host species, with 6.7% of functional orthologs differentially present/absent between host species and bovine-derived strains having the lowest number of genes. Canine-derived isolates were most likely to be non-toxigenic and more likely to carry phages. A targeted study of episomes identified in local pediatric strains showed sharing of a methicillin-resistance plasmid with dogs, and historic sharing of a wide range of episomes across hosts. Bovine-derived isolates harbored the widest variety of antibiotic-resistance genes, followed by canine

Conclusions:

While C. difficile isolates mostly clustered by host species, occasional co-clustering of canine and pediatric-derived isolates suggests the possibility of interspecies transmission. The presence of a pool of resistance genes in animal-derived isolates with the potential to appear in humans given sufficient pressure from antibiotic use warrants concern.

The lung microbiome in lung transplantation

Culture-independent study of the lower respiratory tract after lung transplantation has enabled an understanding of the microbiome - that is, the collection of bacteria, fungi, and viruses, and their respective gene complement - in this niche. The lung has unique features as a microbial environment, with balanced entry from the upper respiratory tract, clearance, and local replication. There are many pressures impacting the microbiome after transplantation, including donor allograft factors, recipient host factors such as underlying disease and ongoing exposure to the microbe-rich upper respiratory tract, and transplantation-related immunosuppression, antimicrobials, and postsurgical changes. To date, we understand that the lung microbiome after transplant is dysbiotic; that is, it has higher biomass and altered composition compared to a healthy lung. Emerging data suggest that specific microbiome features may be linked to host responses, both immune and non-immune, and clinical outcomes such as chronic lung allograft dysfunction (CLAD), but many questions remain. The goal of this review is to put into context our burgeoning understanding of the lung microbiome in the postlung transplant patient, the interactions between microbiome and host, the role the microbiome may play in post-transplant complications, and critical outstanding research questions.

Correlation between intraluminal oxygen gradient and radial partitioning of intestinal microbiota

BACKGROUND & AIMS

The gut microbiota is a complex and densely populated community in a dynamic environment determined by host physiology. We investigated how intestinal oxygen levels affect the composition of the fecal and mucosally adherent microbiota.

METHODS

We used the phosphorescence quenching method and a specially designed intraluminal oxygen probe to dynamically quantify gut luminal oxygen levels in mice. 16S ribosomal RNA gene sequencing was used to characterize the microbiota in intestines of mice exposed to hyperbaric oxygen, human rectal biopsy and mucosal swab samples, and paired human stool samples.

RESULTS

Average Po2 values in the lumen of the cecum were extremely low (<1 mm Hg). In altering oxygenation of mouse intestines, we observed that oxygen diffused from intestinal tissue and established a radial gradient that extended from the tissue interface into the lumen. Increasing tissue oxygenation with hyperbaric oxygen altered the composition of the gut microbiota in mice. In human beings, 16S ribosomal RNA gene analyses showed an increased proportion of oxygen-tolerant organisms of the Proteobacteria and Actinobacteria phyla associated with rectal mucosa, compared with feces. A consortium of asaccharolytic bacteria of the Firmicute and Bacteroidetes phyla, which primarily metabolize peptones and amino acids, was associated primarily with mucus. This could be owing to the presence of proteinaceous substrates provided by mucus and the shedding of the intestinal epithelium.

CONCLUSIONS

In an analysis of intestinal microbiota of mice and human beings, we observed a radial gradient of microbes linked to the distribution of oxygen and nutrients provided by host tissue.

Genome-wide analysis of chromosomal features repressing human immunodeficiency virus transcription

We have investigated regulatory sequences in noncoding human DNA that are associated with repression of an integrated human immunodeficiency virus type 1 (HIV-1) promoter. HIV-1 integration results in the formation of precise and homogeneous junctions between viral and host DNA, but integration takes place at many locations. Thus, the variation in HIV-1 gene expression at different integration sites reports the activity of regulatory sequences at nearby chromosomal positions. Negative regulation of HIV transcription is of particular interest because of its association with maintaining HIV in a latent state in cells from infected patients. To identify chromosomal regulators of HIV transcription, we infected Jurkat T cells with an HIV-based vector transducing green fluorescent protein (GFP) and separated cells into populations containing well-expressed (GFP-positive) or poorly expressed (GFP-negative) proviruses. We then determined the chromosomal locations of the two classes by sequencing 971 junctions between viral and cellular DNA. Possible effects of endogenous cellular transcription were characterized by transcriptional profiling. Low-level GFP expression correlated with integration in (i) gene deserts, (ii) centromeric heterochromatin, and (iii) very highly expressed cellular genes. These data provide a genome-wide picture of chromosomal features that repress transcription and suggest models for transcriptional latency in cells from HIV-infected patients.

Integration site selection by lentiviruses: biology and possible control

Retroviruses integrate into naked DNA in a generally sequence nonspecific fashion, but closer study reveals a variety of forces that influence target site selection. Primary sequence of the target plays a small but detectable role. Proteins bound to target DNA can inhibit integration by blocking access of integration complexes or stimulate integration by distorting DNA. An important example of the latter is DNA distortion in nucleosomal DNA. In vivo integration has not yet been convincingly shown to be biased in favor of any identifiable sequence features, though this could still change in future studies. Many applications of retroviral vectors could be facilitated by targeting integration in vivo to predetermined sites. Towards this end, several groups have studied the properties of fusions of integrase proteins to sequence-specific DNA-binding domains. To date such studies establish that targeting can work well in reactions in vitro, but a variety of obstacles complicate applications in vivo. However, naturally occurring retrotransposons do carry out highly targeted integration using retrovirus-like integrase proteins, fueling long-term hopes for targeting with retroviral integrases as well.

Paired DNA three-way junctions as scaffolds for assembling integrase complexes

Early steps of retroviral replication involve reverse transcription of the viral RNA genome and integration of the resulting cDNA copy into a chromosome of the host cell. The initial DNA breaking and joining steps of integration are carried out by the virus-encoded integrase enzyme. Integrases bind specifically to the ends of the unintegrated viral cDNA but nonspecifically to target DNA. Conventional assays in vitro reveal primarily the nonspecific DNA binding mode, complicating studies of integrase--DNA complexes. Here, we report an investigation of unconventional DNA structures useful for positioning integrase at predetermined sites. We find that paired DNA three-way junctions can be used to mimic branched DNAs normally formed as reaction intermediates. The three-way junctions differ from authentic intermediates in the connectivity of the DNAs, which, in contrast to the authentic intermediate, allow formation of stable DNA structures under physiological conditions. Assays in vitro showed that integrase can direct hydrolysis at sequences resembling the viral cDNA ends within the three-way junction, but not on junctions with mutant sequences. Changing the spacing between the paired three-way junctions disrupted the cleavage pattern, emphasizing the importance of the correct DNA scaffold. DNase I footprinting studies revealed protection of specific bases at the terminus of the LTR in the three-way junction complex, but not on control linear DNA, specifying the locations of tight interactions between integrase and DNA. Paired DNA three-way junctions are attractive reagents for structural studies of integrase-DNA complexes.

A quantitative assay for HIV DNA integration in vivo

Early steps of infection by HIV-1 involve entry of the viral core into cells, reverse transcription to form the linear viral DNA, and integration of that DNA into a chromosome of the host. The unintegrated DNA can also follow non-productive pathways, in which it is circularized by recombination between DNA long-terminal repeats (LTRs), circularized by ligation of the DNA ends or degraded. Here we report quantitative methods that monitor formation of reverse transcription products, two-LTR circles and integrated proviruses. The integration assay employs a novel quantitative form of Alu-PCR that should be generally applicable to studies of integrating viruses and gene transfer vectors.

Identification of a small-molecule binding site at the dimer interface of the HIV integrase catalytic domain

Integration of the reverse-transcribed HIV cDNA into the host DNA is a required step in viral replication. The virus-encoded integrase protein catalyzes the initial DNA breaking and joining reactions that mediate cDNA integration. Here, the identification by X-ray crystallography of a small-molecule binding site on the integrase catalytic domain is reported. The small-molecule family studied consists of a core of arsenic or phosphorus surrounded by four aromatic groups. Two arsenic derivatives were visualized bound to integrase. In each case, two molecules bound at symmetry-related sites on the catalytic domain dimer interface. The first compound studied, tetraphenyl arsonium, did not inhibit integrase. However, a synthetic compound substituting a catechol for one of the phenyl rings, dihydroxyphenyltriphenylarsonium, bound to the same site and did inhibit the enzyme. Changes in the vicinity of the catalytic site were seen with the inhibitory compound only, potentially explaining its mechanism of action. Further substituting phosphonium for arsonium yielded a compound with an IC(50) in the low micromolar range. These findings may be useful in designing new inhibitors of integrase, which is at present the only one of the three HIV enzymes for which clinically useful inhibitors are not available.

Nucleic acid chaperone activity of the ORF1 protein from the mouse LINE-1 retrotransposon

Non-LTR retrotransposons such as L1 elements are major components of the mammalian genome, but their mechanism of replication is incompletely understood. Like retroviruses and LTR-containing retrotransposons, non-LTR retrotransposons replicate by reverse transcription of an RNA intermediate. The details of cDNA priming and integration, however, differ between these two classes. In retroviruses, the nucleocapsid (NC) protein has been shown to assist reverse transcription by acting as a "nucleic acid chaperone," promoting the formation of the most stable duplexes between nucleic acid molecules. A protein-coding region with an NC-like sequence is present in most non-LTR retrotransposons, but no such sequence is evident in mammalian L1 elements or other members of its class. Here we investigated the ORF1 protein from mouse L1 and found that it does in fact display nucleic acid chaperone activities in vitro. L1 ORF1p (i) promoted annealing of complementary DNA strands, (ii) facilitated strand exchange to form the most stable hybrids in competitive displacement assays, and (iii) facilitated melting of an imperfect duplex but stabilized perfect duplexes. These findings suggest a role for L1 ORF1p in mediating nucleic acid strand transfer steps during L1 reverse transcription.

Repair of gaps in retroviral DNA integration intermediates

Diverse mobile DNA elements are believed to pirate host cell enzymes to complete DNA transfer. Prominent examples are provided by retroviral cDNA integration and transposon insertion. These reactions initially involve the attachment of each element 3' DNA end to staggered sites in the host DNA by element-encoded integrase or transposase enzymes. Unfolding of such intermediates yields DNA gaps at each junction. It has been widely assumed that host DNA repair enzymes complete attachment of the remaining DNA ends, but the enzymes involved have not been identified for any system. We have synthesized DNA substrates containing the expected gap and 5' two-base flap structure present in retroviral integration intermediates and tested candidate enzymes for the ability to support repair in vitro. We find three required activities, two of which can be satisfied by multiple enzymes. These are a polymerase (polymerase beta, polymerase delta and its cofactor PCNA, or reverse transcriptase), a nuclease (flap endonuclease), and a ligase (ligase I, III, or IV and its cofactor XRCC4). A proposed pathway involving retroviral integrase and reverse transcriptase did not carry out repair under the conditions tested. In addition, prebinding of integrase protein to gapped DNA inhibited repair reactions, indicating that gap repair in vivo may require active disassembly of the integrase complex.

Retroviral cDNA integration: stimulation by HMG I family proteins

To replicate, a retrovirus must synthesize a cDNA copy of the viral RNA genome and integrate that cDNA into a chromosome of the host. We have investigated the role of a host cell cofactor, HMG I(Y) protein, in integration of human immunodeficiency virus type 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) cDNA. Previously we reported that HMG I(Y) cofractionates with HIV-1 preintegration complexes (PICs) isolated from freshly infected cells. PICs depleted of required components by treatment with high concentrations of salt could be reconstituted by addition of purified HMG I(Y) in vitro. Here we report studies using immunoprecipitation that indicate that HMG I(Y) is associated with MoMLV preintegration complexes. In mechanistic studies, we show for both HIV-1 and MoMLV that each HMG I(Y) monomer must contain multiple DNA binding domains to stimulate integration by HMG I(Y)-depleted PICs. We also find that HMG I(Y) can condense model HIV-1 or MoMLV cDNA in vitro as measured by stimulation of intermolecular ligation. This reaction, like reconstitution of integration, depends on the presence of multiple DNA binding domains in each HMG I(Y) monomer. These data suggest that binding of multivalent HMG I(Y) monomers to multiple cDNA sites compacts retroviral cDNA, thereby promoting formation of active integrase-cDNA complexes.

Cyclodidemniserinol trisulfate, a sulfated serinolipid from the Palauan ascidian Didemnum guttatum that inhibits HIV-1 integrase

[structure--see text] Bioassay-guided fractionation of extracts of the Palauan ascidian Didemnum guttatum led to the isolation of cyclodidemniserinol trisulfate (1) as an inhibitor of HIV-1 integrase, which is an attractive target for anti-retroviral chemotherapy. The structure of cyclodidemniserinol trisulfate (1), the stereochemistry of which was only partially determined, was elucidated by interpretation of NMR and mass spectral data.

Developing a dynamic pharmacophore model for HIV-1 integrase

We present the first receptor-based pharmacophore model for HIV-1 integrase. The development of "dynamic" pharmacophore models is a new method that accounts for the inherent flexibility of the active site and aims to reduce the entropic penalties associated with binding a ligand. Furthermore, this new drug discovery method overcomes the limitation of an incomplete crystal structure of the target protein. A molecular dynamics (MD) simulation describes the flexibility of the uncomplexed protein. Many conformational models of the protein are saved from the MD simulations and used in a series of multi-unit search for interacting conformers (MUSIC) simulations. MUSIC is a multiple-copy minimization method, available in the BOSS program; it is used to determine binding regions for probe molecules containing functional groups that complement the active site. All protein conformations from the MD are overlaid, and conserved binding regions for the probe molecules are identified. Those conserved binding regions define the dynamic pharmacophore model. Here, the dynamic model is compared to known inhibitors of the integrase as well as a three-point, ligand-based pharmacophore model from the literature. Also, a "static" pharmacophore model was determined in the standard fashion, using a single crystal structure. Inhibitors thought to bind in the active site of HIV-1 integrase fit the dynamic model but not the static model. Finally, we have identified a set of compounds from the Available Chemicals Directory that fit the dynamic pharmacophore model, and experimental testing of the compounds has confirmed several new inhibitors.

A new class of HIV-1 integrase inhibitors: the 3,3,3', 3'-tetramethyl-1,1'-spirobi(indan)-5,5',6,6'-tetrol family

Integration is a required step in HIV replication, but as yet no inhibitors of the integration step have been developed for clinical use. Many inhibitors have been identified that are active against purified viral-encoded integrase protein; of these, many contain a catechol moiety. Though this substructure contributes potency in inhibitors, it is associated with toxicity and so the utility of catechol-containing inhibitors has been questioned. We have synthesized and tested a systematic series of derivatives of a catechol-containing inhibitor (1) with the goal of identifying catechol isosteres that support inhibition. We find that different patterns of substitution on the aromatic ring suffice for inhibition when Mn(2+) is used as a cofactor. Importantly, the efficiency is different when Mg(2+), the more likely in vivo cofactor, is used. These data emphasize the importance of assays with Mg(2+) and offer new catechol isosteres for use in integrase inhibitors.

Crystal structure of an active two-domain derivative of Rous sarcoma virus integrase

Integration of retroviral cDNA is a necessary step in viral replication. The virally encoded integrase protein and DNA sequences at the ends of the linear viral cDNA are required for this reaction. Previous studies revealed that truncated forms of Rous sarcoma virus integrase containing two of the three protein domains can carry out integration reactions in vitro. Here, we describe the crystal structure at 2.5 A resolution of a fragment of the integrase of Rous sarcoma virus (residues 49-286) containing both the conserved catalytic domain and a modulatory DNA-binding domain (C domain). The catalytic domains form a symmetric dimer, but the C domains associate asymmetrically with each other and together adopt a canted conformation relative to the catalytic domains. A binding path for the viral cDNA is evident spanning both domain surfaces, allowing modeling of the larger integration complexes that are known to be active in vivo. The modeling suggests that formation of an integrase tetramer (a dimer of dimers) is necessary and sufficient for joining both viral cDNA ends at neighboring sites in the target DNA. The observed asymmetric arrangement of C domains suggests that they could form a rotationally symmetric tetramer that may be important for bridging integrase complexes at each cDNA end.

Dolastatin 3 and two novel cyclic peptides from a palauan collection of Lyngbya majuscula

A collection of Lyngbya majuscula from Palau contained the peptides dolastatin 3 (1), homodolastatin 3 (2), and kororamide (3), together with aplysiatoxin (4), debromoaplysiatoxin (5), and oscillatoxin A (6). The structures of the new peptides homodolastatin 3 (2) and kororamide (3) were determined by interpretation of spectroscopic data and chemical degradation.

Coupled integration of human immunodeficiency virus type 1 cDNA ends by purified integrase in vitro: stimulation by the viral nucleocapsid protein

Integration of retroviral cDNA involves coupled joining of the two ends of the viral genome at precisely spaced positions in the host cell DNA. Correct coupled joining is essential for viral replication, as shown, for example, by the finding that viral mutants defective in coupled joining are defective in integration and replication. To date, reactions with purified human immunodeficiency virus type 1 (HIV-1) integrase protein in vitro have supported mainly uncoupled joining of single cDNA ends. We have analyzed an activity stimulating coupled joining present in HIV-1 virions, which led to the finding that the HIV-1 nucleocapsid (NC) protein can stimulate coupled joining more than 1,000-fold under some conditions. The requirements for stimulating coupled joining were investigated in assays with mutant NC proteins, revealing that mutations in the zinc finger domains can influence stimulation of integration. These findings (i) provide a means for assembling more authentic integrase complexes for mechanistic studies, (ii) reveal a new activity of NC protein in vitro, (iii) indicate a possible role for NC in vivo, and (iv) provide a possible method for identifying a new class of inhibitors that disrupt coupled joining.

The mobility of an HIV-1 integrase active site loop is correlated with catalytic activity

Replication of HIV-1 requires the covalent integration of the viral cDNA into the host chromosomal DNA directed by the virus-encoded integrase protein. Here we explore the importance of a protein surface loop near the integrase active site using protein engineering and X-ray crystallography. We have redetermined the structure of the integrase catalytic domain (residues 50-212) using an independent phase set at 1.7 A resolution. The structure extends helix alpha4 on its N-terminal side (residues 149-154), thus defining the position of the three conserved active site residues. Evident in this and in previous structures is a conformationally flexible loop composed of residues 141-148. To probe the role of flexibility in this loop, we replaced Gly 140 and Gly 149, residues that appear to act as conformational hinges, with Ala residues. X-ray structures of the catalytic domain mutants G149A and G140A/G149A show further rigidity of alpha4 and the adjoining loop. Activity assays in vitro revealed that these mutants are impaired in catalysis. The DNA binding affinity, however, is minimally affected by these mutants as assayed by UV cross-linking. We propose that the conformational flexibility of this active site loop is important for a postbinding catalytic step.

Lamellarin alpha 20-sulfate, an inhibitor of HIV-1 integrase active against HIV-1 virus in cell culture

HIV-1 integrase is an attractive target for anti-retroviral chemotherapy, but to date no clinically useful inhibitors have been developed. We have screened diverse marine natural products for compounds active against integrase in vitro and found a series of ascidian alkaloids, the lamellarins, that show selective inhibition. A new member of the family named lamellarin alpha 20-sulfate (1), the structure of which was determined from spectroscopic data, displayed the most favorable therapeutic index. The site of action of lamellarin alpha 20-sulfate on the integrase protein was mapped by testing activity against deletion mutants of integrase. Inhibition of isolated catalytic domain was detectable though weaker than inhibition of full length integrase; possibly lamellarin alpha 20-sulfate binds a site composed of multiple integrase domains. Lamellarin alpha 20-sulfate also inhibited integration in vitro by authentic HIV-1 replication intermediates isolated from infected cells. Lamellarin alpha 20-sulfate was tested against wild type HIV using the MAGI indicator cell assay and found to inhibit early steps of HIV replication. To clarify the inhibitor target, we tested inhibition against an HIV-based retroviral vector bearing a different viral envelope. Inhibition was observed, indicating that the HIV envelope cannot be the sole target of lamellarin alpha 20-sulfate in cell culture. In addition, these single round tests rule out action against viral assembly or budding. These findings provide a new class of compounds for potential development of clinically useful integrase inhibitors.

Integration complexes derived from HIV vectors for rapid assays in vitro

Of three enzymes encoded by HIV-reverse transcriptase, protease, and integrase-only the first two have been exploited clinically as inhibitor targets. Efforts to develop inhibitors of purified integrase protein have yielded many compounds, but none with clinical utility. A different source of integration activity for studies in vitro is provided by replication intermediates isolated from HIV-infected cells. These preintegration complexes (PICs) can direct integration of the endogenously synthesized viral cDNA into an added target DNA in vitro. Despite their authentic activities, assays of PICs have not been widely used due to technical obstacles, particularly the requirement for handling large amounts of infectious HIV. Here, we describe greatly improved methods for producing PICs using HIV-based vectors that are capable of establishing an integrated provirus but not a spreading infection. We also report the development of a PIC integration assay using DNA-coated microtiter plates, which speeds assays of PIC integration in vitro. We used this method to screen a library of chemicals related to known integrase inhibitors and found a new compound, quinalizarin sulfate, that displayed enhanced activity against PICs.

Molluscum contagiosum virus topoisomerase: purification, activities, and response to inhibitors

Molluscum contagiosum virus (MCV), the only member of the Molluscipoxvirus genus, causes benign papules in healthy people but disfiguring lesions in immunocompromised patients. The sequence of MCV has been completed, revealing that MCV encodes a probable type I topoisomerase enzyme. All poxviruses sequenced to date also encode type I topoisomerases, and in the case of vaccinia virus the topoisomerase has been shown to be essential for replication. Thus, inhibitors of the MCV topoisomerase might be useful as antiviral agents. We have cloned the gene for MCV topoisomerase, overexpressed and purified the protein, and begun to characterize its activities in vitro. Like other eukaryotic type I topoisomerases, MCV topoisomerase can relax both positive and negative supercoils. An analysis of the cleavage of plasmid and oligonucleotide substrates indicates that cleavage by MCV topoisomerase is favored just 3' of the sequence 5' (T/C)CCTT 3', resulting in formation of a covalent bond to the 3' T residue, as with other poxvirus topoisomerases. We identified solution conditions favorable for activity and measured the rate of formation and decay of the covalent intermediate. MCV topoisomerase is sensitive to inhibition by coumermycin A1 (50% inhibitory concentration, 32 microM) but insensitive to five other previously reported topoisomerase inhibitors. This work provides the point of departure for studies of the mechanism of function of MCV topoisomerase and the development of medically useful inhibitors.

Modulation of activity of Moloney murine leukemia virus preintegration complexes by host factors in vitro

We have explored the requirements for host proteins in the integration of Moloney murine leukemia virus (MoMuLV) cDNA in vitro. Following infection, it is possible to lyse cells and obtain preintegration complexes (PICs) capable of integrating the MoMuLV cDNA into an added target DNA in vitro (intermolecular integration). PICs can be stripped of required proteins by gel filtration in high-salt buffers (600 mM KCI), allowing the nature of the removed factors to be investigated by in vitro reconstitution. In a previous study of human immunodeficiency virus type 1 (HIV-1) PICs, the host protein HMG I(Y) was found to be able to restore activity to salt-stripped PICs. In contrast, salt stripping and reconstitution of MoMuLV PICs led to the proposal that a host factor is important for a different activity, blocking integration into the cDNA itself (autointegration). In this report, we investigated reconstitution of salt-stripped MoMuLV PICs and found that addition of cellular extract from uninfected NIH 3T3 cells could block autointegration and also restore intermolecular integration. Isolation of the intermolecular integration-complementing activity yielded HMG I(Y), as in the HIV-1 case. However, HMG I(Y) could not block autointegration, implicating a different host factor in this process. Additionally, when MoMuLV PICs were partially purified but not salt stripped, the intermolecular integration activity was reduced but could be stimulated by the addition of any of several purified DNA binding proteins. In summary, three activities were detected: (i) the intermolecular integration cofactor HMG I(Y), (ii) an autointegration barrier protein, and (iii) stimulatory DNA binding proteins.

Human immunodeficiency virus type 1 preintegration complexes: studies of organization and composition

We have investigated the organization and function of human immunodeficiency virus type 1 (HIV-1) preintegration complexes (PICs), the large nucleoprotein particles that carry out cDNA integration in vivo. PICs can be isolated from HIV-1-infected cells, and such particles are capable of carrying out integration reactions in vitro. We find that although the PICs are large, the cDNA must be condensed to fit into the measured volume. The ends of the cDNA are probably linked by a protein bridge, since coordinated joining of the two ends is not disrupted by cleaving the cDNA internally with a restriction enzyme. cDNA ends in PICs were protected from digestion by added exonucleases, probably due to binding of proteins. The intervening cDNA, in contrast, was susceptible to attack by endonucleases. Previous work has established that the virus-encoded integrase protein is present in PICs, and we have reported recently that the host protein HMG I(Y) is also present. Here we report that the viral matrix and reverse transcriptase (RT) proteins also cofractionated with PICs through several steps whereas capsid and nucleocapsid proteins dissociated. These data support a model of PIC organization in which the cDNA is condensed in a partially disassembled remnant of the viral core, with proteins tightly associated at the apposed cDNA ends but loosely associated with the intervening cDNA. In characterizing the structure of the cDNA ends, we found that the U5 DNA ends created by RT were ragged, probably due to the terminal transferase activity of RT. Only molecules correctly cleaved by integrase protein at the 3' ends were competent to integrate, suggesting that one role for terminal cleavage by integrase may be to create a defined end at otherwise heterogeneous cDNA termini.

Human immunodeficiency virus type 2 preintegration complexes: activities in vitro and response to inhibitors

We have established an assay for the function of preintegration complexes (PICs) of human immunodeficiency virus type 2 (HIV-2) to investigate the integration mechanism and to develop additional methods for screening candidate integration inhibitors. We partially purified HIV-2 PICs and found that they were competent to integrate viral cDNA into target DNA in vitro. Analysis of the structure of integration products on Southern blots revealed forms consistent with those expected for authentic integration products and circular forms containing one and two long terminal repeats. To determine whether in vitro products had the detailed structure expected of integration products formed in vivo, we recovered product molecules and analyzed junctions between viral DNA and target DNA. In the integration junctions of all nine molecules examined, we observed the 5-bp duplication of target sequence characteristic of integration in vivo. We investigated the possible role in integration of Vpx, a protein present in HIV-2 but not HIV-1 and known to be present in viral cores. Although association of Vpx with viral cDNA was detectable, our studies revealed no obvious role of Vpx in integration since the activities of PICs from Vpx- virions were indistinguishable from those of wild type. We have also investigated the use of HIV-2 PICs as tools to screen candidate HIV inhibitors. Assays with HIV-2 PICs, like assays with HIV-1 PICs, were less sensitive to many small molecule inhibitors than were reactions with purified integrase only. Comparing results of assays with PICs from HIV-1 and HIV-2 may be particularly useful, since inhibitors active against both may be more widely useful and less vulnerable to escape mutants.

HIV-1 cDNA integration: requirement of HMG I(Y) protein for function of preintegration complexes in vitro

We present data indicating that a host protein is important for function of HIV-1 preintegration complexes (PICs) in vitro. PICs partially purified from infected cells were subjected to gel filtration in 600 mM KCl, which removed a factor required for integration without fully disrupting PICs. Addition of an extract from uninfected cells restored activity. Fractionation of the complementing activity yielded HMG I(Y), a nonhistone chromosomal protein important for transcriptional control and chromosomal architecture. Complementing activity could be isolated from PICs, and activity could be depleted from such fractions with an antibody against HMG I(Y). Recombinant HMG I(Y) also complemented salt-stripped complexes. The finding that a host protein is required for integration by HIV PICs parallels findings in several well-studied transposition and site-specific recombination systems.

Tethering human immunodeficiency virus type 1 preintegration complexes to target DNA promotes integration at nearby sites

Integration of retroviral cDNA in vivo is normally not sequence specific with respect to the integration target DNA. We have been investigating methods for directing the integration of retroviral DNA to predetermined sites, with the dual goal of understanding potential mechanisms governing normal site selection and developing possible methods for gene therapy. To this end, we have fused retroviral integrase enzymes to sequence-specific DNA-binding domains and investigated target site selection by the resulting proteins. In a previous study, we purified and analyzed a fusion protein composed of human immunodeficiency virus integrase linked to the DNA-binding domain of lambda repressor. This fusion could direct selective integration in vitro into target DNA containing lambda repressor binding sites. Here we investigate the properties of a fusion integrase in the context of a human immunodeficiency virus provirus. We used a fusion of integrase to the DNA binding domain of the zinc finger protein zif268 (IN-zif). Initially we found that the fusion was highly detrimental to replication as measured by the multinuclear activation of a galactosidase indicator (MAGI) assay for infected centers. However, we found that viruses containing mixtures of wild-type integrase and IN-zif were infectious. We prepared preintegration complexes from cells infected with these viruses and found that such complexes directed increased integration near zif268 recognition sites.

Differential inhibition of HIV-1 preintegration complexes and purified integrase protein by small molecules

To replicate, HIV-1 must integrate a cDNA copy of the viral RNA genome into a chromosome of the host. The integration system is a promising target for antiretroviral agents, but to date no clinically useful integration inhibitors have been identified. Previous screens for integrase inhibitors have assayed inhibition of reactions containing HIV-1 integrase purified from an Escherichia coli expression system. Here we compare action of inhibitors in vitro on purified integrase and on subviral preintegration complexes (PICs) isolated from lymphoid cells infected with HIV-1. We find that many inhibitors active against purified integrase are inactive against PICs. Using PIC assays as a primary screen, we have identified three new anthraquinone inhibitors active against PICs and also against purified integrase. We propose that PIC assays are the closest in vitro match to integration in vivo and, as such, are particularly appropriate for identifying promising integration inhibitors.

Target-sequence preferences of HIV-1 integration complexes in vitro

Integration of reverse transcribed retroviral cDNA is not restricted to particular host DNA sequences. However, the frequency of integration into a particular phosphodiester bond is influenced by the local sequence. Here we examine the target-sequence preferences of purified HIV integrase and viral nucleoprotein complexes (preintegration complexes) isolated from freshly infected cells. We find that the three-base sequence including the integration site is not the major factor determining the frequency of integration, since identical triplets embedded in different sequences are used with very different efficiencies. However, there is a statistically significant bias against integration upstream of a pyrimidine nucleotide. The target-sequence preferences of purified integrase and preintegration complexes are very different. Strong integration sites on opposite DNA strands occur in pairs separated by five residues when preintegration complexes are used but not with purified integrase. These studies highlight the difference between the two sources of HIV integration activity and may provide the basis for a simple assay for the correct assembly of viral nucleoprotein complexes.

In vitro integration of human immunodeficiency virus type 1 cDNA into targets containing protein-induced bends

Integration of human immunodeficiency virus type 1 cDNA into a target DNA can be strongly influenced by the conformation of the target. For example, integration in vitro is sometimes favored in target DNAs containing sequence-directed bends or DNA distortions caused by bound proteins. We have analyzed the effect of DNA bending by studying integration into two well-characterized protein-DNA complexes: Escherichia coli integration host factor (IHF) protein bound to a phage IHF site, and the DNA binding domain of human lymphoid enhancer factor (LEF) bound to a LEF site. Both of these proteins have previously been reported to bend DNA by approximately 140 degrees. Binding of IHF greatly increases the efficiency of in vitro integration at hotspots within the IHF site. We analyzed a series of mutants in which the IHF site was modified at the most prominent hotspot. We found that each variant still displayed enhanced integration upon IHF binding. Evidently the local sequence is not critical for formation of an IHF hotspot. LEF binding did not create preferred sites for integration. The different effects of IHF and LEF binding can be rationalized in terms of the different proposed conformations of the two protein-DNA complexes.

Human immunodeficiency virus type 1 preintegration complexes containing discontinuous plus strands are competent to integrate in vitro

Despite intensive study, the mechanism by which many retroviruses complete reverse transcription has remained unclear. Most retroviruses and all lentiviruses fail to synthesize a full-length second strand of the viral cDNA (plus strand) efficiently in infected cells. For human immunodeficiency virus type 1, we find in synchronous infection experiments that full-length plus strands are rare (< 1% of products) at times when integration is likely taking place. Subviral nucleoprotein complexes containing such discontinuous cDNA can be extracted from infected cells and used to generate integration products in vitro. Analysis of such integration products using two-dimensional gel electrophoresis revealed that the discontinuous viral DNA was efficiently integrated into an added target DNA. These data support a model in which the discontinuities in the plus strand need not be sealed until after integration, potentially by the enzymes that are already thought to repair DNA gaps at the junctions between host and viral DNA.

HIV integration. Ini1 for integration?

The newly discovered Ini1 cellular protein binds HIV-1 integrase and is part of a protein complex thought to alter nucleosomal structure; such alterations may influence the selection of sites for HIV-1 DNA integration.

The influence of DNA and nucleosome structure on integration events directed by HIV integrase

DNA copies of the human immunodeficiency virus (HIV) genome integrate nonrandomly into the chromosomal DNA of the host cell. In this report, we investigate the molecular basis of this selectivity using the virus-encoded HIV integrase to direct integration of a synthetic HIV long terminal repeat substrate into either DNA molecules of known structure or previously defined nucleosomal complexes. We find that the structure of the target greatly influences the site of integration, and, moreover, DNA curvature, flexibility, and rigidity in solution all influence the frequency of integration. Importantly, for DNA with all of these properties, the distortion of the double helix directed by association with the histone proteins promotes the integration reaction and alters the distribution of sites that are selected for integration. We suggest that both intrinsic DNA structure and the folding of DNA into chromosomal structures will exert a major influence on target site selection for integration of the viral genome.

Tethering human immunodeficiency virus 1 integrase to a DNA site directs integration to nearby sequences

Certain retrovirus and retrotransposons display strong biases in the selection of host DNA sites for integration. To probe the possibility that simple tethering of the retroelement integrase protein to a target DNA site is sufficient to direct integration, the activities of a hybrid composed of human immunodeficiency virus 1 integrase and lambda repressor were analyzed. In in vitro reactions containing several target DNAs, the lambda repressor-integrase hybrid was found to direct integration selectively to targets containing lambda operators. Addition of lambda repressor blocked selective integration, indicating that binding to the operators was required. The lambda repressor-integrase hybrid protein directed integration primarily to sites near the operators on the same face of the B-DNA helix, indicating that target DNA was probably captured by looping out the intervening sequences. Such hybrid integrase proteins may be useful for directing retroviral integration to specific sequences in vivo.

Human immunodeficiency virus integrase directs integration to sites of severe DNA distortion within the nucleosome core

We have examined the consequences of DNA distortion and specific histone-DNA contacts within the nucleosome for integration mediated by the human immunodeficiency virus (HIV)-encoded integrase enzyme. We find that sites of high-frequency integration cluster in the most severely deformed, kinked DNA regions within the nucleosome core. This may reflect either a preference for a wide major groove for association of the integrase or a requirement for target DNA distortion in the DNA strand transfer mechanism. Both the distortion and folding of the target DNA through packaging into nucleosomes may influence the selection of HIV integration sites within the chromosome.

Rous sarcoma virus integrase protein: mapping functions for catalysis and substrate binding

Rous sarcoma virus (RSV), like all retroviruses, encodes an integrase protein that is responsible for covalently joining the reverse-transcribed viral DNA to host DNA. We have probed the organization of functions within RSV integrase by constructing mutant derivatives and assaying their activities in vitro. We find that deletion derivatives lacking the amino-terminal 53 amino acids, which contain the conserved H-X(3-7)-H-X(23-32)-C-X(2)-C (HHCC) Zn(2+)-binding motif, are greatly impaired in their ability to carry out two reactions characteristic of integrase proteins: specific cleavage of the viral DNA termini and DNA strand transfer. Deletion mutants lacking the carboxyl-terminal 69 amino acids are also unable to carry out these reactions. However, all deletion mutants that retain the central domain are capable of carrying out disintegration, an in vitro reversal of the normal DNA strand transfer reaction, indicating that the catalytic center probably lies within this central region. Another conserved motif, D-X(39-58)-D-X(35)-E, is found in this central domain. These findings with RSV integrase closely parallel previous findings with human immunodeficiency virus integrase, indicating that a modular catalytic domain is a general feature of this family of proteins. Surprisingly, and unlike results obtained so far with human immunodeficiency virus integrase, efficient strand transfer activity can be restored to a mutant RSV integrase lacking the amino-terminal HHCC domain by fusion to various short peptides. Furthermore, these fusion proteins retain the substrate specificity of RSV integrase. These data support a model in which the integrase activities required for strand transfer in vitro, including substrate recognition, multimerization, and catalysis, all lie primarily outside the amino-terminal HHCC domain.

Identification of discrete functional domains of HIV-1 integrase and their organization within an active multimeric complex

HIV-1 integrase protein possesses the 3' processing and DNA strand transfer activities that are required to integrate HIV DNA into a host chromosome. The N-, C-terminal and core domains of integrase are necessary for both activities in vitro. We find that certain pairs of mutant integrase proteins, which are inactive when each protein is assayed alone, can support near wild type levels of activity when both proteins are present together in the reaction mixture. This complementation implies that HIV-1 integrase functions as a multimer and has enabled us to probe the organization of the functional domains within active mixed multimers. We have identified a minimal set of functional integrase domains that are sufficient for 3' processing and DNA strand transfer and find that some domains are contributed in trans by separate monomers within the functional complex.

Domains of the integrase protein of human immunodeficiency virus type 1 responsible for polynucleotidyl transfer and zinc binding

The integrase protein of human immunodeficiency virus type 1 carries out a set of polynucleotidyl transfer reactions that result in the covalent attachment of the retroviral cDNA to host DNA. We have analyzed the activities of a set of deletion derivatives of the integrase protein. The analysis reveals that a central domain of only 137 amino acids is sufficient in vitro to catalyze a subset of the reactions carried out by the complete protein. This polypeptide contains an amino acid sequence motif, Asp-Xaa39-58-Asp-Xaa35-Glu (DX39-58DX35E, where X and the subscript indicate the intervening amino acids between the invariant acidic residues), that is found in the integrases of retroviruses and retrotransposons and also the transposase proteins of some bacterial transposable elements. We also find that the integrase protein can bind Zn2+, and the histidine and cysteine residues of another conserved motif (HX3-7HX23-32CX2C) are required for efficient Zn2+ binding. The activities displayed by deletion mutants suggest to us possible functions for the various parts of integrase.

The bacteriophage 434 right operator. Roles of O(R)1, O(R)2 and O(R)3

Lysogenic induction of bacteriophage lambda is controlled by the action of the phage repressor and Cro proteins at the phage right operator (O(R)). This study examines the roles of the repressor and Cro proteins of the related phage 434. The start sites of transcription of the divergently oriented promoters in the 434 O(R) region, PR and PRM, were mapped, and the effects of 434 repressor and Cro on promoter activity were assessed using promoter fusions to lacZ. The effects of repressor or Cro bound to each of the operator subsites (O(R)1, O(R)2 and O(R)3) were assessed by examining regulation in the presence of operator mutations. The binding of Cro to a 434 operator was probed by an ethylation interference experiment which, together with other data, indicates that 434 Cro and repressor probably turn off transcription by blocking binding of RNA polymerase to promoter sequences. In general, the 434 and lambda right operators are controlled in a similar fashion, but differences in detail were also encountered: (1) 434 Cro represses transcription from PR primarily by binding to O(R)1, whereas binding of lambda Cro to O(R)1 and O(R)2 contribute equally to repression. (2) The 434 cI message, unlike that of lambda, has a recognizable homology to the Shine-Dalgarno ribosome binding site. (3) Occupancy of O(R)3 by repressor may be somewhat greater in a 434 lysogen than in a lambda lysogen. (4) The 434 repressor probably activates transcription when bound at O(R)2 by contacting RNA polymerase, as does lambda repressor, but also by influencing competition between PR and PRM. An analysis of the six right operator systems for which data are available indicates that all six repressors may employ the mechanism of transcriptional activation first described for lambda, P22 and 434: apposition of an acidic surface to a particular part of RNA polymerase.

Integration of human immunodeficiency virus DNA: adduct interference analysis of required DNA sites

The integration (IN) protein encoded by human immunodeficiency virus directs the integration of viral DNA into host DNA. We have probed the DNA sites required for the function of IN protein by attaching adducts to model DNA substrates and assaying their effects on integration in vitro. These experiments reveal that modifications in a short region on both DNA strands at the ends of the viral DNA block IN protein function. Modification of the target DNA near the point of DNA strand transfer also blocks IN protein function. Further experiments suggest that distinct subsets of the identified interactions are important for separate steps in the integration process.

A rapid in vitro assay for HIV DNA integration

Retroviruses synthesize a double stranded DNA copy of their RNA genome after infection of a permissive cell and subsequent integration of this DNA copy into the host genome is necessary for normal viral replication. Integration occurs by a specialized DNA recombination reaction, mediated by the viral IN protein. Because this reaction has no known cellular counterpart, it is a particularly attractive target in the search for specific inhibitors with low toxicity that may serve as therapeutic antiviral agents. We present a simple assay system that is suitable for screening potential inhibitors of HIV DNA integration. Only short oligonucleotides matching one end of HIV DNA and purified HIV IN protein are required as substrates. Furthermore, since each step of the assay can be carried out in the wells of microtiter plates, large numbers of reactions can be processed simultaneously.

Activities of human immunodeficiency virus (HIV) integration protein in vitro: specific cleavage and integration of HIV DNA

Growth of human immunodeficiency virus (HIV) after infection requires the integration of a DNA copy of the viral RNA genome into a chromosome of the host. Here we present a simple in vitro system that carries out the integration reaction and the use of this system to probe the mechanism of integration. The only HIV protein necessary is the integration (IN) protein, which has been overexpressed in insect cells and then partially purified. DNA substrates are supplied as oligonucleotides that match the termini of the linear DNA product of reverse transcription. In the presence of HIV IN protein, oligonucleotide substrates are cleaved to generate the recessed 3' ends that are the precursor for integration, and the cleaved molecules are efficiently inserted into a DNA target. Analysis of reaction products reveals that HIV IN protein joins 3' ends of the viral DNA to 5' ends of cuts made by IN protein in the DNA target. We have also used this assay to characterize the sequences at the ends of the viral DNA involved in integration. The assay provides a simple screen for testing candidate inhibitors of HIV IN protein; some such inhibitors might have useful antiviral activity.

Sequence requirements for integration of Moloney murine leukemia virus DNA in vitro

Normal replication of Moloney murine leukemia virus (MoMLV) requires the integration of a DNA copy of the viral RNA genome into a chromosome of the host. In this work, we characterize the DNA sequences at the ends of the linear proviral precursor that are required for integration in the presence of MoMLV integration protein in vitro. We found that nine bases of MoMLV DNA at each end of a linear model substrate were sufficient for near-maximal levels of integration and that four bases of MoMLV DNA at each end were sufficient for low levels of correct integration. We also found that a 3'-terminal A residue was preferred for integration. We infer from the limited DNA sequence requirements for integration that factors in addition to DNA sequence direct integration protein to act at the ends of the viral DNA.

Retroviral DNA integration directed by HIV integration protein in vitro

Efficient retroviral growth requires integration of a DNA copy of the viral RNA genome into a chromosome of the host. As a first step in analyzing the mechanism of integration of human immunodeficiency virus (HIV) DNA, a cell-free system was established that models the integration reaction. The in vitro system depends on the HIV integration (IN) protein, which was partially purified from insect cells engineered to express IN protein in large quantities. Integration was detected in a biological assay that scores the insertion of a linear DNA containing HIV terminal sequences into a lambda DNA target. Some integration products generated in this assay contained five-base pair duplications of the target DNA at the recombination junctions, a characteristic of HIV integration in vivo; the remaining products contained aberrant junctional sequences that may have been produced in a variation of the normal reaction. These results indicate that HIV IN protein is the only viral protein required to insert model HIV DNA sequences into a target DNA in vitro.

A single glutamic acid residue plays a key role in the transcriptional activation function of lambda repressor

Previous experiments have suggested that negative charge is an important aspect of the activating region of lambda repressor as it is for at least one class of eukaryotic transcriptional activators. Here we randomize amino acids in the activating region of repressor and assay the function of over 100 variants. We find that acidic residues at the four solvent-exposed positions on the surface of an alpha helix (helix 2 in the structure) together comprise a strong activating region. Only one of these acidic residues, however, is critical for activation, and at this position glutamate is strongly preferred to aspartate. At the three remaining positions, certain uncharged residues (different ones at each position) function as well as or better than the acidic residues. Basic residues, however, are highly detrimental to function at all four positions. Our mutagenesis studies also suggest limitations on amino acid substitutions that allow formation of the helix-turn-helix DNA binding motif found in repressor and in many other DNA binding regulatory proteins.

Activation of transcription by the bacteriophage 434 repressor

Bacteriophage 434 encodes a repressor that, like bacteriophage lambda repressor, both activates and represses transcription. As in the lambda chromosome, a region of the 434 chromosome, called the right operator, contains three repressor binding sites (OR1, OR2, and OR3) that mediate these effects on two adjacent promoters. We now show that a part of the 434 repressor, the amino-terminal domain, activates leftward transcription when bound to OR2. We show that 434 repressor bound to OR2 closely approaches (touches) RNA polymerase bound to the leftward promoter. Model building based on ethylation interference and other experiments suggests that in three cases, those involving lambda repressor, 434 repressor, and bacteriophage P22 repressor, and in spite of differences in detailed arrangements, transcription is activated by a contact between the repressor and the same part of RNA polymerase.

Ethylation interference and X-ray crystallography identify similar interactions between 434 repressor and operator

In the crystal structure of a repressor-operator complex (the 434 repressor DNA-binding domain and its 14-base pair (bp) operator), Anderson et al. elsewhere in this issue identify six positions of likely contact between repressor protein and phosphates of the DNA backbone. At each of these positions, electron densities of protein and DNA merge. Experiments presented here indicate that intact 434 repressor approaches these phosphates very closely when it is bound to DNA in solution. Specifically, when any one of these phosphates is ethylated, repressor cannot bind to the modified operator. We also identify another position where ethylation has a significant but less dramatic effect on repressor binding, and note that in the structure, repressor closely approaches this phosphate. Our results strongly support the idea that the interactions between protein and the DNA phosphate backbone in the crystallized complex are the same as those made by intact repressor to operator DNA in solution. In addition, our results suggest that DNA is slightly bent by repressor binding.