Adenovirus 5 E1A Interacts with E4orf3 To Regulate Viral Chromatin Organization.

Human adenovirus expresses several early proteins that control various aspects of the viral replication program, including an orchestrated expression of viral genes. Two of the earliest viral transcriptional units activated after viral genome entry into the host cell nucleus are the E1 and E4 units, which each express a variety of proteins. Chief among these are the E1A proteins that function to reprogram the host cell and activate transcription of all other viral genes. The E4 gene encodes multiple proteins, including E4orf3, which functions to disrupt cellular antiviral defenses, including the DNA damage response pathway and activation of antiviral genes. Here we report that E1A directly interacts with E4orf3 via the conserved N terminus of E1A to regulate the expression of viral genes. We show that E4orf3 indiscriminately drives high nucleosomal density of viral genomes, which is restrictive to viral gene expression and which E1A overcomes via a direct interaction with E4orf3. We also show that during infection E1A colocalizes with E4orf3 to nuclear tracks that are associated with heterochromatin formation. The inability of E1A to interact with E4orf3 has a significant negative impact on overall viral replication, the ability of the virus to reprogram the host cell, and the levels of viral gene expression. Together these results show that E1A and E4orf3 work together to fine-tune the viral replication program during the course of infection and highlight a novel mechanism that regulates viral gene expression.IMPORTANCE To successfully replicate, human adenovirus needs to carry out a rapid yet ordered transcriptional program that executes and drives viral replication. Early in infection, the viral E1A proteins are the key activators and regulators of viral transcription. Here we report, for the first time, that E1A works together with E4orf3 to perfect the viral transcriptional program and identify a novel mechanism by which the virus can adjust viral gene expression by modifying its genome's nucleosomal organization via cooperation between E1A and E4orf3.

A naturally occurring transcript variant of MARCO reveals the SRCR domain is critical for function.

Macrophage receptor with collagenous structure (MARCO) is a class A scavenger receptor (cA-SR) that recognizes and phagocytoses a wide variety of pathogens. Most cA-SRs that contain a C-terminal scavenger receptor cysteine-rich (SRCR) domain use the proximal collagenous domain to bind ligands. In contrast, the role of the SRCR domain of MARCO in phagocytosis, adhesion and pro-inflammatory signaling is less clear. The discovery of a naturally occurring transcript variant lacking the SRCR domain, MARCOII, provided the opportunity to study the role of the SRCR domain of MARCO. We tested whether the SRCR domain is required for ligand binding, promoting downstream signaling and enhancing cellular adhesion. Unlike cells expressing full-length MARCO, ligand binding was abolished in MARCOII-expressing cells. Furthermore, co-expression of MARCO and MARCOII impaired phagocytic function, indicating that MARCOII acts as a dominant-negative variant. Unlike MARCO, expression of MARCOII did not enhance Toll-like receptor 2 (TLR2)-mediated pro-inflammatory signaling in response to bacterial stimulation. MARCO-expressing cells were more adherent and exhibited a dendritic-like phenotype, whereas MARCOII-expressing cells were less adherent and did not exhibit changes in morphology. These data suggest the SRCR domain of MARCO is the key domain in modulating ligand binding, enhancing downstream pro-inflammatory signaling and MARCO-mediated cellular adhesion.

Bison and bighorns: Assessing the potential impacts of reintroducing a large herbivore to a mountainous landscape.

The reintroduction of wildlife can have significant ecological impacts by altering the flow of energy in food webs. Recently, plains bison were reintroduced to part of Banff National Park after a 150-year absence. The large herbivore's reintroduction was expected to have far-reaching effects on the ecosystem due to its significant energy requirements and interactions with habitat and other sympatric species. This study explores the impacts of bison reintroduction on the movement and resource use of another large-bodied grazer, the Rocky Mountain bighorn sheep. Between 2018 and 2021, we collected data from GPS collars fit on 39 bighorn sheep and 11 bison. We analyzed home range patterns, resource selection, and interactions to investigate the potential for interspecific competition, facilitation, and resource complementarity. At the population level, bison and bighorn sheep exhibited low levels of spatial overlap and there was strong evidence of resource separation in all seasons. Interactions between species did not appear to affect sheep movement rates; however, we did see differences in forage selection patterns for sheep with overlapping home ranges with bison. Collectively, results did not support the potential for competition or facilitation between bison and bighorn sheep and instead provided the strongest evidence of complementarity.

Characterization of the 55-residue protein encoded by the 9S E1A mRNA of species C adenovirus.

Early region 1A (E1A) of human adenovirus (HAdV) has been the focus of over 30 years of investigation and is required for the oncogenic capacity of HAdV in rodents. Alternative splicing of the E1A transcript generates mRNAs encoding multiple E1A proteins. The 55-residue (55R) E1A protein, which is encoded by the 9S mRNA, is particularly interesting due to the unique properties it displays relative to all other E1A isoforms. 55R E1A does not contain any of the conserved regions (CRs) present in the other E1A isoforms. The C-terminal region of the 55R E1A protein contains a unique sequence compared to all other E1A isoforms, which results from a frameshift generated by alternative splicing. The 55R E1A protein is thought to be produced preferentially at the late stages of infection. Here we report the first study to directly investigate the function of the species C HAdV 55R E1A protein during infection. Polyclonal rabbit antibodies (Abs) have been generated that are capable of immunoprecipitating HAdV-2 55R E1A. These Abs can also detect HAdV-2 55R E1A by immunoblotting and indirect immunofluorescence assay. These studies indicate that 55R E1A is expressed late and is localized to the cytoplasm and to the nucleus. 55R E1A was able to activate the expression of viral genes during infection and could also promote productive replication of species C HAdV. 55R E1A was also found to interact with the S8 component of the proteasome, and knockdown of S8 was detrimental to viral replication dependent on 55R E1A.

Human papillomavirus 18 E1

The human papilloma virus E4 protein is highly expressed in late times of infection. Evidence to date suggests that E4 is essential for amplification of the viral genome and that it can influence cell cycle. Examination of the sequences encoding the E4 proteins from several genotypes of human papillomavirus revealed the presence of RXL-containing motifs reminiscent of the cyclin-binding motifs that have been identified in several cyclin-binding proteins. When baculovirus-produced human cyclin E and cyclin A with cdk2 were incubated in vitro with a GST-E4 fusion protein, both cyclin E and A stably interacted with the GST-E4 protein containing the full E4 sequence from HPV18. The interaction was not dependent on the presence of the kinase subunit but was dependent on the integrity of the RXL motif in E4. When incubated with cell extracts from the C33A human cervical carcinoma cell line or when expressed in C33A cells, the GST-E4 protein formed interactions with cyclin A and cdk2 and kinase activity could be demonstrated in the GST-E4 complex. In contrast to the baculovirus-produced cyclin E, cellular cyclin E failed to detectably interact with GST-E4 suggesting that the HPV18 E4 sequences are capable of interacting only with cyclin A in mammalian cells. These observations suggest that human papillomavirus E4 proteins can interact with cyclin A/cdk2, which may contribute to viral manipulation of the host cell cycle.

Adenovirus E1A directly targets the E2F/DP-1 complex.

Deregulation of the cell cycle is of paramount importance during adenovirus infection. Adenovirus normally infects quiescent cells and must initiate the cell cycle in order to propagate itself. The pRb family of proteins controls entry into the cell cycle by interacting with and repressing transcriptional activation by the E2F transcription factors. The viral E1A proteins indirectly activate E2F-dependent transcription and cell cycle entry, in part, by interacting with pRb and family members to free the E2Fs. We report here that an E1A 13S isoform can unexpectedly activate E2F-responsive gene expression independently of binding to the pRb family of proteins. We demonstrate that E1A binds to E2F/DP-1 complexes through a direct interaction with DP-1. E1A appears to utilize this binding to recruit itself to E2F-regulated promoters, and this allows the E1A 13S protein, but not the E1A 12S protein, to activate transcription independently of interaction with pRb. Importantly, expression of E1A 13S, but not E1A 12S, led to significant enhancement of E2F4 occupancy of E2F sites of two E2F-regulated promoters. These observations identify a novel mechanism by which adenovirus deregulates the cell cycle and suggest that E1A 13S may selectively activate a subset of E2F-regulated cellular genes during infection.

Cyclin D1/cdk4 can interact with E2F4/DP1 and disrupts its DNA-binding capacity.

The E2F family of transcription factors regulate the expression of many growth-related genes in a cell cycle-dependent manner. These transcription factors can activate or, in conjunction with an Rb-related protein, repress transcription. E2F transcriptional activity is regulated at several different levels that are each linked to cell cycle progression. In many cell types, E2F4 and E2F5 are the predominant E2F species during G(0) and early G(1) and function primarily as repressors of E2F-regulated genes. In this study, co-immunoprecipitation techniques were used to demonstrate that cyclins D1, D2, and D3 are capable of interacting with E2F4, E2F5, and DP1. Overexpression of cyclin D1/cdk4 reduced E2F4-mediated transcription in a simple reporter gene assay and electrophoretic mobility shift analyses using nuclear extracts from transfected cells indicated that cyclin D1/cdk4 disrupts the DNA-binding ability of E2F4. Cell cycle analysis following stimulation of serum-starved 3T3 cells indicated that E2F4 undergoes changes in its phosphorylation pattern coincident with the synthesis of cyclin D1. Examination of a series of E2F4 deletion mutants indicated that a cyclin D1-binding site located close to the carboxyl terminus of E2F4 was critical for the disruption of DNA binding by cyclin D1/cdk4. These data support a model in which E2F4 DNA binding is abolished during mid-G(1) at the same time when E2F interactions with pRb-related proteins are disrupted by cyclin D1/cdk4.

BMI1 reduces ATR activation and signalling caused by hydroxyurea.

BMI1 facilitates DNA damage response (DDR) induced by double strand DNA breaks; however, it remains unknown whether BMI1 functions in single strand DNA (ssDNA) lesions-initiated DDR. We report here that BMI1 reduces hydroxyurea-elicited ATR activation, thereby reducing the S-phase checkpoints. Hydroxyurea induces ssDNA lesions, which activate ATR through binding TOPBP1 as evidenced by phosphorylation of ATR at threonine 1989 (ATRpT1989). ATR subsequently phosphorylates H2AX at serine 139 (γH2AX) and CHK1 at serine 345 (CHK1pS345), leading to phosphorylation of CDK1 at tyrosine 15 (CDK1pY15) and S-phase arrest. BMI1 overexpression reduced γH2AX, CHK1pS345, CDK1pY15, S-phase arrest, and ATR activation in HU-treated MCF7 and DU145 cells, whereas BMI1 knockdown enhanced these events. BMI1 contains a ring finger, helix-turn, proline/serine domain and two nuclear localization signals (NLS). Individual deletion of these domains did not abolish BMI1-derived reductions of CHK1pS345 in MCF7 cells following HU exposure, suggesting that these structural features are not essential for BMI1 to attenuate ATR-mediated CHK1pS345. BMI1 interacts with both TOPBP1 and ATR. Furthermore, all of our BMI1 mutants associate with endogenous TOPBP1. It has previously been established that association of TOPBP1 and ATR is required for ATR activation. Thus, our results suggest that BMI1 decreases ATR activation through a mechanism that involves binding to TOPBP1 and/or ATR.

Urban Compost Attracts Coyotes, Contains Toxins, and may Promote Disease in Urban-Adapted Wildlife.

Anthropogenic food is often concentrated in cities where it can attract wildlife, promote conflict with people, and potentially spread disease. Although these associations are well-documented for conventional garbage, they are unexplored for many seemingly innocuous and even environmentally friendly attractants such as piles of compost. In this study, we tested the hypothesis that municipal piles of compost are underappreciated and potentially important contributors to a recent rise in encounters with urban-adapted wildlife by attracting wildlife and promoting the spread of wildlife disease. We used remote cameras to compare visitation rates to compost piles and urban natural areas by coyotes (Canis latrans). For each site type, we assessed photographs for evidence of ectoparasites, screened scats for endoparasites, and sampled compost for harmful mycotoxins. At compost piles, visitation rates were eight times more frequent, coyotes with visible parasitic infections were 4.5 times more common, scats were 10 times more likely to contain tapeworm eggs, and mycotoxins were detected in 86% of piles and often at concentrations higher than legal limits for animal feed. Greater securement of compost waste in cities may reduce encounters with animals, susceptibility to and spread of disease, and rates of human-wildlife conflict for coyotes and other urban-adapted species.

Adenovirus E1A proteins direct subcellular redistribution of Nek9, a NimA-related kinase.

A monoclonal antibody raised against adenovirus E1A-associated cellular proteins recognized Nek9, a NimA-related protein kinase. Subcellular fractionation and immunofluorescence indicated that Nek9 was primarily cytoplasmic with a small portion located in the nucleus whereas E1A was primarily nuclear. Although co-immunoprecipitation experiments indicated that nuclear Nek9 interacted, directly or indirectly, with E1A, the major effect of E1A was to diminish the amount of Nek9 in the nucleus suggesting that E1A alters the subcellular distribution of Nek9 and that the interaction is transient. A Nek9 deletion mutant lacking a central RCC1-like domain interacted stably with E1A and accumulated in the nucleus in the presence of E1A, possibly representing an intermediate stage of the normally transient Nek9/E1A interaction. The interaction of Nek9 with E1A was dependent on the N-terminal sequences of E1A. Attempts to stably overexpress either Nek9 or the kinase-inactive mutant in various cell lines were unsuccessful; however, the presence of E1A allowed stable overexpression of both proteins. These results suggest that E1A disrupts a nuclear function of Nek9.