New way to image whole organisms in 3D brings key skin color pigment
into focus
Date:
October 5, 2021
Source:
Penn State
Summary:
To understand the biological underpinnings of skin and hair
pigmentation and related diseases such as albinism or melanoma,
scientists and doctors need quantitative, three-dimensional
information about the architecture, content and location of pigment
cells. Researchers have developed a new technique that allows
scientists to visualize every cell containing melanin pigment in
3D, in whole zebrafish.
FULL STORY ==========================================================================
To understand the biological underpinnings of skin and hair pigmentation
and related diseases such as albinism or melanoma, scientists and doctors
need quantitative, three-dimensional information about the architecture, content and location of pigment cells. Penn State College of Medicine researchers have developed a new technique that allows scientists to
visualize every cell containing melanin pigment in 3D, in whole zebrafish.
========================================================================== Studying melanin is challenging because it blocks the light used in
traditional microscopy. So the researchers turned to X-ray imaging,
which can pass through optically opaque matter like melanin.
In 2019, a team led by Dr. Keith Cheng, distinguished professor of
pathology, pharmacology and biochemistry and molecular biology, developed "X-ray histotomography" -- a cellular form of CT imaging, as a method
for investigating the 3D architecture of cells and tissues in biological samples at unprecedented resolution and clarity. Spencer Katz, an MD/PhD medical scientist training program student on Cheng's team, has modified
this micro-CT technique to specifically investigate melanin, a pigment scientists are studying in human skin color and melanoma research,
in whole zebrafish.
Melanin is a brown to black pigment that gives the zebrafish its
characteristic stripes and humans dark skin, hair and eyes. More than
15 years ago, Cheng and his lab discovered a key gene in the evolution
of light skin color in humans by studying a particular mutant zebrafish
line, golden, that has lighter stripes.
This discovery demonstrated the relevance of zebrafish models for studying critical questions about human biology and disease, including albinism
and melanoma.
Micro-CT, like human CT, uses a series of X-rays taken at slightly
different angles to compute, or reconstruct, 3D representations of the
original object.
For micro-CT, the samples are smaller and the resolution developed by
Cheng's team is 2000-fold higher. Katz used silver to stain the melanin,
which allowed the researchers to determine the 3D location and density
of melanin from scans of whole zebrafish.
To perform the imaging, the Cheng Lab partnered with Dilworth Parkinson
at the Advanced Light Source at the Lawrence Berkeley National Labs
in Berkeley, California -- home of one of America's most powerful
synchrotron X-ray sources, where he directs a micro-CT resource suitable
for Cheng's X-ray histotomography. The lab's new X-ray detector system
was designed to achieve resolutions unprecedented for samples the size
of whole zebrafish or human biopsies. The team scanned zebrafish with
both normal and altered pigmentation, including golden.
The researchers were able to visualize every cell containing melanin,
called melanocytes, in the fish, and map each of their positions in
3D. Moreover, they could get quantitative measurements of their melanin content, allowing direct comparison of melanin content across normal
and mutant fish for the first time.
They published the results of their study in eLife.
This work laid a foundation for further research on melanin-containing
cancers, or melanomas, which are typically graded by the depth of tumor
cell invasion.
According to Cheng, a researcher at Penn State Cancer Institute, a
number of zebrafish models of melanoma exist and can be studied using
the new technique.
Katz and Cheng said that human melanomas can be stained with silver and
imaged in the same way to more completely characterize the tumor cells
and their arrangements in tumors. They predict that scientists will be
able to, for example, count the number of tumor cells of different characteristics and more definitively study invasion, a central
characteristic of cancer, helping doctors with prognostic and treatment decisions.
In the future, the Cheng Lab will continue to develop new staining and
optical methods for expanding the applications of histotomography. This
study represents a proof-of-principle for how whole-body, 3D computational analysis of organisms and tissues can be achieved using micro-CT that
may allow a far more complete understanding of gene function.
Maksim Yakovlev, Daniel Vanselow, Yifu Ding, Alex Lin, Victor Canfield
and Khai Chung Ang of Penn State College of Medicine also contributed
to this research.
The new lens system used in the study was designed and built by Yuxin
Wang of Mobile Imaging Innovations Inc. The authors declared no competing interests.
This research was supported by the National Institutes of Health, the Pennsylvania Department of Health Tobacco CURE Funds, the Jake Gittlen Laboratories for Cancer Research at Penn State College of Medicine, Penn
State Huck Institutes of the Life Sciences and Penn State Institute for Computational and Data Sciences.
This study utilized the College of Medicine's zebrafish functional
genomics core and represents activities of the Penn State Center for
Artificial Intelligence Foundations and Scientific Applications and computational phenomics initiatives.
========================================================================== Story Source: Materials provided by Penn_State. Note: Content may be
edited for style and length.
========================================================================== Journal Reference:
1. Spencer R Katz, Maksim A Yakovlev, Daniel J Vanselow, Yifu Ding,
Alex Y
Lin, Dilworth Y Parkinson, Yuxin Wang, Victor A Canfield, Khai C
Ang, Keith C Cheng. Whole-organism 3D quantitative characterization
of zebrafish melanin by silver deposition micro-CT. eLife, 2021;
10 DOI: 10.7554/eLife.68920 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2021/10/211005175421.htm
--- up 4 weeks, 5 days, 8 hours, 25 minutes
* Origin: -=> Castle Rock BBS <=- Now Husky HPT Powered! (1:317/3)