Tag: biomineralisation

Unraveling iron uptake and magnetosome formation in magnetospirillum gryphiswaldense

Unraveling iron uptake and magnetosome formation in magnetospirillum gryphiswaldense

Diamond Light Source sheds light on bacterial biomineralisation processes

Iron plays several essential roles in bacteria, making it a crucial element for their survival and function. In magnetotactic bacteria like Magnetospirillum gryphiswaldense, iron plays a central role in the formation of magnetosomes. These peculiar bacteria possess the capability to orient themselves along the Earth’s magnetic field lines, thanks to the presence of a very specific type of intracellular magnetic nanoparticles called magnetosomes. Magnetosomes are mainly composed of magnetite crystals (Fe3O4) enveloped in a lipidic membrane. Some mechanisms such as the internalisation and the transformation of iron into magnetite crystals are still poorly understood. In an article recently published in ACS Applied Materials & Interfaces, a team of researchers from Aston University investigated the formation of these magnetosomes in bacteria by finely tuning the concentration of oxygen and iron. They performed CryoSIM and CryoSXT experiments on the B24 beamline. The team were also the first to exploit the recent development of the beamline to measure X-ray absorption data at the Iron L3 edge to aid visualisation of the magnetsomes.

Advancing understanding of bacterial magnetosome formation

Magnetosome formation in magnetotactic bacteria is a complex process influenced by environmental factors such as iron concentration and oxygen levels. Prior studies provided foundational knowledge but lacked the resolution to observe these processes at the single-cell level under near-native conditions. Given the small size of magnetosomes, which can range from 30 nm to 120 nm across different species, electron microscopy is one of the most common used imaging techniques. However, this approach does not enable simultaneous tracking of intracellular iron content alongside magnetosome content to understand better how the biomineralisation process works. This research aimed to bridge that gap by employing an integrated approach combining correlative light and X-ray microscopy with other analytical techniques.

Firstly, the data obtained from these other analytical techniques suggested a potential correlation between the intracellular iron pool and magnetosome content. Specifically, increased iron availability under microaerobic conditions appeared to result in longer magnetosome chains and higher intracellular iron concentrations. To further investigate and validate this hypothesis at the single-cell level, the researchers conducted experiments at the B24 beamline at Diamond.

Utilising Diamond Light Source for advanced imaging

Cryo-SXT is a powerful technique used to observe the internal structure of biological samples in a near-native state. This technique uses soft-X rays to obtain three-dimensional (3D) tomograms of biological specimens with a resolution of up to 25 nm, without the need for traditional sample preparation methods that could damage cellular structures (such as drying, chemical fixation, staining). On B24, the team was able to observe internal compartments, including magnetosomes, using the preferential absorption of carbon atoms in the cell. With cryoSIM, they stained the bacteria with PG-SK, a green fluorophore that reacts with the intracellular iron. The strength of the B24 beamline is that scientists were able to analyse the same region of interest in the same samples with both CryoSIM and CryoSXT and correlate the data.

This approach provided compelling evidence of a correlation between the intracellular iron concentration and the number of magnetosomes. Another advantage of using soft X-ray microscopy at B24 is the ability to adjust the X-ray energy to the iron absorption edge. As iron atoms strongly absorb X-rays at this energy, it facilitates the observation of magnetosomes within the bacteria. By modifying the iron concentration during bacterial growth, the researchers demonstrated that these bacteria can tolerate high extracellular iron concentrations. They also identified an iron threshold beyond which increasing the extracellular iron concentration no longer leads to additional iron uptake or an increase in magnetosome production.

Read more on Diamond website

Bioinspired controlled crystallisation: Towards sustainable artificial coral reefs

Bioinspired controlled crystallisation: Towards sustainable artificial coral reefs

Inspired by nature, scientists have replicated some aspects of the biomineralisation process used by marine organisms like corals, enabling them to control crystal phases in materials. This advancement could lead, among others, to artificial coral reefs that seamlessly integrate into marine environments without disrupting the ecosystem. Their results are out in Advanced Functional Materials.

Artificial coral reefs are often made of concrete or steel to provide stable structures for a marine habitat. However, they can also foster biofilm formation, promoting bacterial growth that may influence water chemistry.

Now a team led by Boaz Pokroy at Technion Israel Institute of Technology is working on artificial coral reefs that are as close to their natural counterparts as possible by reproducing the biomineralisation process typical of coral reefs and other marine organisms.

“For many years, we’ve extensively studied many marine organisms, such as the coralline alga Jania sp., sea urchins, starfish or brittle stars, and have unveiled the steps these organisms take to create a super hard skeleton through the process of biomineralisation”, explains Pokroy.

The natural process of biomineralisation starts as an amorphous phase before transforming into crystalline stable structures.

A key player in in this process is amorphous calcium carbonate (ACC), a precursor that can crystallise into different forms of calcium carbonate, including calcite, aragonite, and vaterite. The stability of ACC is influenced, among other factors, by impurities like magnesium, which affects the final crystal structure and properties. Traditionally, controlling this transformation required chemical additives and environmental adjustments.

Pokroy and his team used lasers to selectively transform ACC into different mineral phases. Laser power, scanning speed and the composition of the substrate are factors that affect the process of formation of distinct crystalline phases.

As the next step, the powders were analysed using synchrotron high-resolution powder X-ray diffraction (HR-PXRD) to identify the phases formed. “The experiments on beamline ID22 at the ESRF were crucial to characterise the different phases and track the impurities in the sample”, explains Hadar Shaked, scientist at Technion and first author of the publication. “With EBS providing higher flux, we were able to scan hundreds of samples in a very short time”, adds Pokroy.

Engineering bio-inspired materials

This method represents a significant advancement in bio-inspired material science, offering a way to engineer complex mineral structures with the same spatial accuracy seen in biological systems. “Whilst crystallisation from an amorphous phase was already possible through heating, it is the first time that we have full control of the process, which is key in engineering new structures as we wish”, says Shaked.

Dubbed ‘writing crystallography’, this approach opens exciting possibilities not only for artificial coral reefs but also for advanced additive manufacturing, semiconductors or single-layer patterning, where precise phase control is essential.

Read more on ESRF website