by Diamond Light Source
B24 cryo-SXT projection images of areas inside HeLa cells infected by C. trachomatis. These human cells were infected with C. trachomatis and imaged at B24 after 24 hours using either a 40 nm objective (panel on the left) or 25 nm objective (E) (the field of view decreases as image resolution decreases). The left panel captures a whole inclusion with resident bacteria attached on the inside surface (dark roughly circular shapes). The right panel shows an area of the interior of an inclusion with a variable bacterial population. Mit: mitochondria, N: nucleus, EB: elementary body, RB: reticulate, IM: inclusion membrane, ER: endoplasmic reticulum body, LD: lipid droplets, black arrow: inner bacterial membrane invagination. Credit: Diamond Light Source
Best known as the cause of a sexually transmitted infection, Chlamydiae are a diverse group of pathogens whose strains can also lead to pneumonia and blindness.
Chlamydiae form communities inside the cells of their hosts in compartments known as ‘inclusions.’ During their life cycle they transition between two forms, responsible for replication within a host cell and infection of neighboring cells respectively.
But little is known about how this infection system works in practice, or how the nature of Chlamydiae communities influences the individual bacteria members within them. Such knowledge could open up new treatment avenues for the diseases caused by these pathogens.
The senior author of this new study, which uses cutting-edge cryo-Soft X-ray Tomography (cryo-SXT) at the correlative cryo-imaging beamline B24 at Diamond to investigate this pathogen, is Dr. Maud Dumoux. Dr. Dumoux, Technology Lead for cryo-imaging at the Rosalind Franklin Institute, said: “Chlamydiae are unique bacteria, as they grow only inside cells. Most strains form a specialized compartment in which hundreds—sometimes thousands—of bacteria multiply and differentiate themselves between non-infectious and infectious forms, preparing for release into the wider environment to infect other cells in the body. How communities of Chlamydiae organize these events, and how each community has an impact on its individual bacteria, are intriguing questions that have implications beyond this particular pathogen.”
Credit: Diamond Light Source
In this paper, the research team—from the Franklin, Diamond Light Source, Research Complex at Harwell, and Oxford University—sought to uncover how communities of Chlamydiae bacteria regulate and organize their space, and how basic factors such as concentration and size of bacteria can impact the life cycle. To do this, the researchers used the correlative cryo-imaging capacity of beamline B24 and specifically, the transmission X-ray microscope for cryo-SXT data collection.
Dr. Maria Harkiolaki, Principal Beamline Scientist at B24, explains further: “The techniques we use allow us to inspect delicate structures in cells and find out how things are organized inside them. Cryo-SXT data collection at this beamline is done through a rapid user-friendly process that captures intra-cellular behavior and interactions quickly and in intricate detail. B24 is one of only four facilities in the world that provides this technology. Surprisingly, we found that concentration of bacteria is not correlated with differentiation into the infectious form. In other words, at the time we observed the infected cells , a high concentration did not trigger preparation for exiting the cell and infecting other cells . However, we did show that higher concentrations lead to smaller individual bacteria, whereas bacteria given space can reach very large volumes—similar to the apocryphal idea that fish will grow to the size of their pond. This is very interesting because it demonstrates, as is often the case in life science, that things are not black and white. Here, there are shades of gray as the bacteria adapt or respond to their environmental pressures. It also opens up new questions about whether different types of bacteria have different roles within the community.”
The researchers conclude that each ‘inclusion’ (a specialized compartment of bacteria within an infected human cell) operates as an autonomous community that influences the characteristics of individual bacteria within it, and that bacterial concentration is a key factor in determining those characteristics. With cryo-SXT now established as a useful and rapid technique for studying Chlamydiae, future research will shed light on the evolution of infection and communication between bacterial communities, which could open up new therapeutic opportunities.
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https://phys.org/news/2021-09-x-ray-imaging-technique-cells-hosting.html