A viral nucleus

Cell typesA unique feature of eukaryotic cells, which distinguishes them from bacteria, is the presence of a membrane-bound nucleus that contains the chromosomal DNA (illustrated; image credit). Surprisingly, a nucleus-like structure that forms during viral infection of bacteria is the site of viral DNA replication (link to paper).

During infection of Pseudomonas bacteria with the phage 2O1phi2-1, a separate compartment forms in which viral DNA replication takes place. A phage protein, gp105, makes up the outer layer of this compartment, which initially forms near one end of the cell, and then migrates to the center. The migration of the compartment takes place on a spindle made up of the tubulin-like protein PhuZ.

In addition to viral DNA, certain proteins gain entry into this compartment, including viral proteins involved in DNA and mRNA synthesis, and at least one host cell protein. Other proteins, such as those involved in translation and nucleotide synthesis, are excluded. This compartmentalization very much resembles that of the nucleus of eukaryotic cells.

Packaging of the viral DNA takes place on the surface of the viral nucleus. Empty phage capsids form at the bacterial cytoplasmic membrane, then migrate to the compartment where they attach firmly to the surface. By an unknown mechanism, DNA moves from the compartment into the capsid. Then  capsids are released from the surface to further mature in the cytoplasm. The completed phages are released from the cell upon bacterial lysis.

These fascinating observations raise a number of unanswered questions. Does infection with other phages lead to assembly of a viral nucleus? How do molecules selectively move in and out of the structure?

Perhaps the most interesting question relates to the origin of viruses and cells. According to one hypothesis, self-replicating, virus-like nucleic acids might have first appeared on Earth, followed by cells without a nucleus. Was the nucleus a viral invention?

I spoke with Jonna Mazet, PhD, UC Davis School of Veterinary Medicine, about emerging pathogen surveillance and public health. Dr. Mazet is the Principal Investigator and Global Director of the novel viral emergence early warning project, PREDICT, that has been developed with the US Agency for International Development’s (USAID) Emerging Pandemic Threats Program. Recorded at the Emerging Infectious Diseases A to Z (EIDA2Z) conference hosted by the National Emerging Infectious Diseases Laboratories (NEIDL).

TWiV 424: FLERVergnügen

Trudy joins the the TWiVlords to discuss new tests for detecting prions in the blood, and evidence showing that foamy retroviruses originated in the seas with their jawed vertebrate hosts at least 450 million years ago.

You can find TWiV #424 at microbe.tv/twiv, or listen below.

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I spoke with virologist Ian Goodfellow, whose laboratory works on noroviruses, about why he went to Sierra Leone to establish an Ebolavirus diagnostic and sequencing laboratory. The obstacles he encountered were considerable, but the results were very useful. Recorded at the Emerging Infectious Diseases A to Z (EIDA2Z) conference hosted by the National Emerging Infectious Diseases Laboratories (NEIDL).

PCMA for prionsA sensitive and specific blood test has been developed that could be used to limit the risk of transmission of prion disease through the blood supply (link to papers one and two).

Prion diseases, also known as spongiform encephalopathies, are uniformly fatal, chronic degenerative neurological diseases caused by misfolding of a cellular protein, PrPC. Transmissible encephalopathies may be acquired by organ transplant, receiving contaminated blood, or the ingestion of contaminated food.

In the 1990s a new spongiform encephalopathy, variant Creutzfeld-Jakob disease or vCJD, began to appear in Great Britain. Variant Creutzfeld-Jakob disease is caused by prions acquired by the consumption of cattle with bovine spongiform encephalopathy, also a prion disease affectionately known as mad cow disease. To date 231 cases of vCJD have been reported, mainly in the UK and France.

Although the spread of BSE has been controlled by surveillance and feeding restrictions, it is estimated that millions of people were exposed to BSE prions. The concern is that some of these individuals might be infected but show no symptoms of disease. If they donate blood, they may transmit infection to others. It is known that several cases of vCJD have been transmitted from infected blood donors, so further transmission is a major concern. So far prion diseases have only been diagnosed after death, by detection of conformationally altered prion proteins in the brain.

Two sensitive and specific assays for vCJD prions have now been developed that show promise for non-invasive pre-symptomatic diagnosis of the disease. They are both based on a technology called protein misfolding cyclic amplification (PMCA, illustrated; image copyright ASM Press, 2015). A small amount of the normal human prion protein, PrPC (produced in transgenic mice) is mixed with plasma. The samples are incubated to allow formation of prion oligomers, followed by disruption by a pulse of sonication to disrupt the oligomers. The cycle is repeated multiple times, much like polymerase chain reaction (PCR) which is used to amplify small amounts of DNA. Prions are detected by western blot analysis after treatment with proteinase K. The misfolded, pathogenic prions, PrPSC , are not completely digested with this enzyme.

In one study, PMCA was used to analyze blood samples from 14 cases of vCJD and 153 controls, which included healthy individuals and those with other neurological diseases, including sporadic CJD (sCJD – not caused by ingestion of contaminated beef). All 14 samples from cases of vCJD were positive in the PMCA assay, but not any of the other samples.

In a second study, the PMCA assay was positive in samples from all 18 patients with vCJD. Of 134 control samples, just one was positive for vCDJ, from a patient with sCJD. Furthermore, the assay detected vCJD prions in archived blood samples from donors who gave blood before developing symptoms of the disease.

These findings suggest that the new assays can detect vCJD prions in the blood before the appearance of the neurological symptoms of spongiform encephalopathy. While additional samples must be analyzed to validate the results, they are nonetheless promising as a way to prevent spread of the disease via the blood supply. Unfortunately, if you are diagnosed with vCJD by one of these assays, that is the only positive outcome – there are as yet no treatments for any spongiform encephalopathy.

The TWiV academia discuss induction of diarrhea by the capsid protein of an astrovirus, and association of a fungal RNA virus with white-nose syndrome of North American bats.

You can find TWiV #423 at microbe.tv/twiv, or listen below.

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SiphoviridaeVirus infections initiate when virions bind to receptors on the cell surface. It is well known that cells can be made susceptible to infection by providing DNA encoding the virus receptor. For example, mice cannot be infected with poliovirus, but become susceptible if they are given the human poliovirus receptor gene. Now we have learned that providing the receptor protein is sufficient to make cells susceptible to infection (link to paper).

Bacteriophages determine the composition of microbial populations by killing some bacteria and sparing others. Bacteriophages are typically host specific, a property that is largely determined at the level of attachment to host cell receptors. How resistant and sensitive bacteria in mixed communities respond to phage infection has not been well studied.

Several phages (including SPP1, pictured) of the soil bacterium Bacillus subtilis first attach to poly-glycosylated teichoic acids (gTA), and then to the membrane protein YueB, leading to injection of DNA into the cell. Cells that lack the gene encoding either of these proteins are resistant to infection.

When a mixed culture of resistant and susceptible B. subtilis cells were infected with phage SPP1, both types of cells became infected and killed. Infection of resistant cells depended on the presence of susceptible cells, because no infection occurred in pure cultures of resistant cells.

Both infected and uninfected bacteria release small membrane vesicles that contain proteins, nucleic acids, and other molecules. Phage SPP1 can attach to  membrane vesicles released by susceptible strains of B. subtilis, showing that they contain viral receptor proteins. Furthermore, phage SPP1 can infect resistant cells that have been incubated with membrane vesicles from a susceptible strain – in the absence of intact susceptible cells.

These results show that membrane vesicles released by susceptible bacteria contain viral receptors that can be inserted into the membrane of a resistant cell, allowing infection. Because phage infection can lead to transfer of host DNA from one cell to another, the results have implications for the movement of genes for antibiotic resistance or virulence. It’s possible that such genes may move into bacteria that have only ‘temporarily’ received virus receptors via membrane vesicle transfer.

These findings should also be considered when designing phage therapy for infectious diseases. The idea is to utilize phages that are host specific and can only destroy the disease-producing bacteria. It’s possible that the host range of such phages could be expanded by receptor protein transfer. As a consequence, unwanted genes might make their way into ‘resistant’ bacteria.

I wonder if membrane vesicle mediated transfer of receptors also occurs in eukaryotic cells. They shed membrane vesicles called exosomes, which contain protein and RNA that are delivered to other cells. If exosomes bear receptors for viruses, they might be able to deliver the receptors to cells that would not normally be infected. The types of cells infected by a virus would thereby be expanded, potentially affecting the outcome of viral disease.

Vincent Racaniello interviews Harmit Malik, PhD, Fred Hutchinson Cancer Research Center. Harmit and his laboratory are interested in a variety of problems that are characterized by evolutionary conflict.

This video is one of 26 video interviews with eminent virologists that are part of the supplemental material for Principles of Virology, 4th Edition, published by ASM Press. Other interviews in this series can be found at this link.

The TWiVestigators wrap up 2016 with a discussion of the year’s ten compelling virology stories.

You can find TWiV #422 at microbe.tv/twiv, or listen below.

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TWiV 421: Like flies on shot

The TWiVnauts present another example of an infectious but replication incompetent vaccine, an insect specific arborvirus bearing chikungunya virus structural proteins.

You can find TWiV #421 at microbe.tv/twiv, or listen below.

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