Structural analysis of a Synechococcus myovirus S-CAM4 and infected cells by atomic force microscopy

Bacterial surface interactions with organic colloidal particles: Nanoscale hotspots of organic matter in the ocean

Colloidal particles constitute a substantial fraction of organic matter in the global ocean and an abundant component of the organic matter interacting with bacterial surfaces. Using E. coli ribosomes as model colloidal particles, we applied high-resolution atomic force microscopy to probe bacterial surface interactions with organic colloids to investigate particle attachment and relevant surface features. We observed the formation of ribosome films associating with marine bacteria isolates and natural seawater assemblages, and that bacteria readily utilized the added ribosomes as growth substrate. In exposure experiments ribosomes directly attached onto bacterial surfaces as 40–200 nm clusters and patches of individual particles. We found that certain bacterial cells expressed surface corrugations that range from 50–100 nm in size, and 20 nm deep. Furthermore, our AFM studies revealed surface pits in select bacteria that range between 50–300 nm in width, and 10–50 nm in depth. Our findings suggest novel adaptive strategies of pelagic marine bacteria for colloid capture and utilization as nutrients, as well as storage as nanoscale hotspots of DOM.

Windows into Microbial Seascapes: Advances in Nanoscale Imaging and Application to Marine Sciences

Geochemical cycles of all nonconservative elements are mediated by microorganisms over nanometer spatial scales. The pelagic seascape is known to possess microstructure imposed by heterogeneous distributions of particles, polymeric gels, biologically important chemicals, and microbes. While indispensable, most traditional oceanographic observational approaches overlook this heterogeneity and ignore subtleties, such as activity hot spots, symbioses, niche partitioning, and intrapopulation phenotypic variations, that can provide a deeper mechanistic understanding of planktonic ecosystem function. As part of the movement toward cultivation-independent tools in microbial oceanography, techniques to examine the ecophysiology of individual populations and their role in chemical transformations at spatial scales relevant to microorganisms have been developed. This review presents technologies that enable geochemical and microbiological interrogations at spatial scales ranging from 0.02 to a few hundred micrometers, particularly focusing on atomic force microscopy, nanoscale secondary ion mass spectrometry, and confocal Raman microspectroscopy and introducing promising approaches for future applications in marine sciences.

Bacteriophage electron microscopy

Since the advent of the electron microscope approximately 70 years ago, bacterial viruses and electron microscopy are inextricably linked. Electron microscopy proved that bacteriophages are particulate and viral in nature, are complex in size and shape, and have intracellular development cycles and assembly pathways. The principal contribution of electron microscopy to bacteriophage research is the technique of negative staining. Over 5500 bacterial viruses have so far been characterized by electron microscopy, making bacteriophages, at least on paper, the largest viral group in existence. Other notable contributions are cryoelectron microcopy and three-dimensional image reconstruction, particle counting, and immunoelectron microscopy. Scanning electron microscopy has had relatively little impact. Transmission electron microscopy has provided the basis for the recognition and establishment of bacteriophage families and is one of the essential criteria to classify novel viruses into families. It allows for instant diagnosis and is thus the fastest diagnostic technique in virology. The most recent major contribution of electron microscopy is the demonstration that the capsid of tailed phages is monophyletic in origin and that structural links exist between some bacteriophages and viruses of vertebrates and archaea. DNA sequencing cannot replace electron microscopy and vice versa.

An atomic force microscopy investigation of cyanophage structure

Marine viruses have only relatively recently come to the attention of molecular biologists, and the extraordinary diversity of potential host organisms suggests a new wealth of genetic and structural forms. A promising technology for characterizing and describing the viruses structurally is atomic force microscopy (AFM). We provide examples here of some of the different architectures and novel structural features that emerge from even a very limited investigation, one focused on cyanophages, viruses that infect cyanobacteria (blue-green algae). These were isolated by phage selection of viruses collected from California coastal waters. We present AFM images of tailed, spherical, filamentous, rod shaped viruses, and others of eccentric form. Among the tailed phages numerous myoviruses were observed, some having long tail fibers, some other none, and some having no visible baseplate. Syphoviruses and a podovirus were also seen. We also describe a unique structural features found on some tailed marine phages that appear to have no terrestrial homolog. These are long, 450 nm, complex helical tail fibers terminating in a unique pattern of 3+1 globular units made up of about 20 small proteins.

Procapsid assembly, maturation, nuclear exit: dynamic steps in the production of infectious herpesvirions

Herpesviruses, a family of animal viruses with large (125-250 kbp) linear DNA genomes, are highly diversified in terms of host range; nevertheless, their virions conform to a common architecture. The genome is confined at high density within a thick-walled icosahedral capsid with the uncommon (among viruses, generally) but unvarying triangulation number T = 16. The envelope is a membrane in which some 11 different viral glycoproteins are implanted. Between the capsid and the envelope is a capacious compartment called the tegument that accommodates ∼20-40 different viral proteins (depending on which virus) destined for delivery into a host cell. A strong body of evidence supports the hypothesis that herpesvirus capsids and those of tailed bacteriophages stem from a distant common ancestor, whereas their radically different infection apparatuses - envelope on one hand and tail on the other - reflect subsequent coevolution with divergent hosts. Here we review the molecular components of herpesvirus capsids and the mechanisms that regulate their assembly, with particular reference to the archetypal alphaherpesvirus, herpes simplex virus type 1; assess their duality with the capsids of tailed bacteriophages; and discuss the mechanism whereby, once DNA packaging has been completed, herpesvirus nucleocapsids exit from the nucleus to embark on later stages of the replication cycle.

Investigation of bacteriophage T4 by atomic force microscopy

Bacteriophage T4 was visualized using atomic force microscopy (AFM). The images were consistent with, and complementary to electron microscopy images. Head heights of dried particles containing DNA were about 75 nm in length and 60 nm in width, or about 100 nm and 85 nm respectively when scanned in fluid. The diameter of hydrated tail assemblies was 28 nm and their lengths about 130 nm. Seven to eight pronounced, right-handed helical turns with a pitch of 15 nm were evident on the tail assemblies. At the distal end of the tail was a knob shaped mass, presumably the baseplate. The opposite end, where the tail assembly joins the head, was tapered and connected to the portal complex, which was also visible. Phage that had ejected their DNA revealed the internal injection tube of the tail assembly. Heads disrupted by osmotic shock yielded boluses of closely packed DNA that unraveled slowly to expose threads composed of multiple twisted strands of nucleic acid. Assembly errors resulted in the appearance of several percent of the phage exhibiting two rather than one tail assemblies that were consistently oriented at about 72° to one another. No pattern of capsomeres was visible on native T4 heads. A mutant that is negative for the surface proteins hoc and soc, however, clearly revealed the icosahedral arrangement of ring shaped capsomeres on the surface. The hexameric rings have an outside diameter of about 14 nm, a pronounced central depression, and a center-to-center distance of 15 nm. Phage collapsed on cell surfaces appeared to be dissolving, possibly into the cell membrane.