• Interaction with lung cells transforms a

    From ScienceDaily@1:317/3 to All on Thu Feb 24 21:30:42 2022
    Interaction with lung cells transforms asbestos particles
    To better understand what happens once asbestos enters a human body, researchers took a nanoscale look at the mineral

    Date:
    February 24, 2022
    Source:
    University of Pennsylvania
    Summary:
    Asbestos fibers can cause lung cancer and other diseases, often
    multiple decades following exposure. Many researchers have sought
    to elucidate disease mechanisms, but a new study took the opposite
    approach, using a high-tech microscope to look at how the mineral
    changed upon interaction with lung cells. Their findings suggest
    that the mineralogical transformations inside the cells may play
    a role in triggering disease.



    FULL STORY ==========================================================================
    A common building material, asbestos is the term used to describe
    a range of naturally growing minerals. Serious diseases, including
    mesothelioma and lung cancer, can arise decades after coming into contact
    with asbestos.


    ========================================================================== Biomedical researchers have spent many years trying to understand how
    asbestos causes disease, though multiple pieces of the puzzle remain
    unknown. Taking a completely different approach, an international team
    led by researchers at the University of Pennsylvania, looked instead at
    how the interactions change the mineral itself.

    "Many studies have looked at the toxicity of asbestos, and we wanted
    to approach this issue from the opposite side, not investigating the
    effects on the cells, but rather exploring what happens to the mineral
    once inside the cell," says Reto Giere', a professor in Penn's Department
    of Earth and Environmental Science in the School of Arts & Sciences,
    and senior author on the work, published in Scientific Reports.

    "We used cutting-edge experimental techniques, going down to the nanoscale
    and even the atomic scale to see the transformation of the minerals," says first author Ruggero Vigliaturo, now a tenure-track assistant professor
    at Italy's University of Turin who completed the research during a
    postdoctoral fellowship at Penn. "What we saw is that the minerals are undergoing changes that almost look like they're defending themselves
    from the cells." The research grew out of a larger set of experiments on asbestos undertaken through Penn's Center of Excellence in Environmental Toxicology. Though a common term, the word "asbestos" is not a scientific
    one, but rather is used in industry to refer to a wide range of minerals
    with varying structures and chemical compositions. In the current work, Vigliaturo, Giere', and colleagues focused on amphibole asbestos, which
    is hypothesized to be more hazardous than other varieties.

    While much research into asbestos toxicity has focused on how the body's tissues respond to the mineral, here the researchers wanted to observe how
    the mineral responded to being taken up by human lung cells. Collaborating
    with researchers at the National Institute of Chemistry in Slovenia,
    Vigliaturo and Giere' made use of imaging technology with an extremely high-spatial resolution to characterize the minerals after two days
    spent inside human lung cells. In contrast, most asbestos research has
    so far focused on impacts on the body when long asbestos fibers remain
    in areas of tissue outside of cells.



    ==========================================================================
    With specialized transmission electron microscopy (TEM) techniques,
    the researchers documented never-before-seen changes in the amphibole
    minerals, many of which were taken up by compartments in the cell called lysosomes, which typically are involved in processing cellular waste
    and programmed cell death.

    "In these lysosomes, which are more acidic than the rest of the cell, we observed that the surface of the mineral starts dissolving," says Giere'.

    An immediate question about these relatively iron-rich minerals quickly
    arose: "What was the fate of the iron?" he says.

    A refined type of TEM analysis allowed the researchers to see that the oxidation state of iron was changing during this dissolution, alterations
    that could influence the way the mineral reacted with other cellular components, such as organelles and cell nuclei.

    The mineral surfaces also underwent striking changes, which included the formation of an iron-rich, amorphous layer after being internalized by the cells. To the scientists, the layer was reminiscent of asbestos bodies,
    but with marked structural and chemical differences. Asbestos bodies are
    formed by macrophages in the lung tissue rather than inside the cells,
    and are associated with extended exposure to asbestos.



    ========================================================================== "When you examine samples of lung tissue extracted from patients that
    succumbed to asbestos-related diseases, you'll find asbestos fibers
    surrounded by a brownish coating. These are asbestos bodies," Giere'
    says. "The coating is biogenically formed, and the iron is delivered
    primarily from the body through a protein called ferritin." In their experiments, with the asbestos inside the cells rather than in the intercellular space, the researchers did not observe asbestos bodies,
    but rather an iron layer on the minerals that was derived from the
    mineral itself.

    And unlike asbestos bodies, these coatings did not contain phosphorous.

    "Why this happens, we don't know," Giere' says. "It may be the cell is attempting to protect itself by triggering this change in the mineral
    but it's too early to say." In addition, Vigliaturo notes that the more iron-rich amphiboles unexpectedly showed less pronounced dissolution
    and a less extensive amorphous layer than the varieties that contained
    less iron. "This was the opposite of what we anticipated and what was
    reported in abiotic experiments," he says.

    The mineralogic changes, the researchers say, could impact how the
    body responds and deals with the asbestos fibers -- a process that may
    have links to how disease arises decades later. They caution, however,
    that their experiments were carried out over a short time frame, just
    two days, and conducted in vitro with cell lines rather than within the
    human body. More work is necessary, they say, to understand whether what
    they observe is reflected in living people exposed to asbestos.

    Giere', Vigliaturo, and their colleagues continue to explore the
    interaction of lung cells and asbestos, but with a focus on the
    biochemical changes in the cells themselves. They're also experimenting
    with different types of asbestos to better understand how their
    similarities and differences may relate to disease burden.

    They hope that their findings will help other researchers interpret
    the toxic and carcinogenic effects of asbestos. And for Vigliaturo, who
    was born in Casale Monferrato, Italy, a city of 40,000 people with more
    than 3,000 deaths attributed to asbestos toxicity from a local factory,
    the desire to learn more about asbestos-related disease is personal.

    "We took nanoscience, biology, and nanomaterials technology and brought
    it to mineralogy," he says. "We're using our specialized backgrounds
    to contribute to solving this part of the puzzle." Reto Giere' is a
    professor in the Department of Earth and Environmental Science in the
    School of Arts & Sciences at the University of Pennsylvania.

    Ruggero Vigliaturo was a postdoctoral researcher in the Department of
    Earth and Environmental Science in the School of Arts & Sciences at Penn
    and is now a tenure-track assistant professor at the University of Turin.

    Vigliaturo and Giere''s coauthors on the work were Maja Jamnik,
    Goran Dražić, Marjetka Podobnik, and Simon Caserman of the
    National Institute of Chemistry of Ljubljana, Slovenia; Magda Tusek Žnidarič of the National Institute of Biology of Ljubljana,
    Slovenia; Giancarlo Della Ventura of the Roma Tre University; Gu"nther
    J. Redhammer of University of Salzburg; and Nada Žnidarsič
    of University of Ljubljana.

    The work was supported by Rotary Global, the Slovenian Research Agency,
    and the National Institute of Environmental Health Sciences (grants
    ES013508 and ES023720).

    ========================================================================== Story Source: Materials provided by University_of_Pennsylvania. Note:
    Content may be edited for style and length.


    ========================================================================== Journal Reference:
    1. Ruggero Vigliaturo, Maja Jamnik, Goran Dražić, Marjetka
    Podobnik, Magda Tusek Žnidarič, Giancarlo Della Ventura,
    Gu"nther J. Redhammer, Nada Žnidarsič, Simon Caserman,
    Reto Giere'. Nanoscale transformations of amphiboles within human
    alveolar epithelial cells. Scientific Reports, 2022; 12 (1) DOI:
    10.1038/s41598- 022-05802-x ==========================================================================

    Link to news story: https://www.sciencedaily.com/releases/2022/02/220224161754.htm

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