Chimeric
antigen receptors (CARs) have opened up an exciting new field of therapeutic
advancements for rare and difficult-to-treat cancers, as they have the ability
to deliver targeted therapies that can kill tumor cells.
Peptide-centric CARs (PC-CARs) rely on specific
peptide "barcodes," which are derived from proteins within the cell
created by potentially cancer-causing oncogenes, are designed to find and target cancer cells. These
"barcodes" are displayed by human leukocyte antigens (HLAs), which
help the immune system distinguish its own proteins from foreign invaders, like
viruses.
However, HLAs are derived from the most
"polymorphic" genes, with more than 25,000 alleles—stretches of DNA
that code for proteins that carry out essential functions—that could vary
between them, making it difficult to design PC-CARs that target the specific
alleles associated with different cancers.
Now, researchers from two closely collaborating labs
at Children's Hospital of Philadelphia (CHOP) have solved a three-dimensional
protein structure that explains how PC-CARs can recognize the
"backbones" of these HLA complexes. The structural information will
now allow researchers to understand how CARs recognize tumor-associated
antigens among different polymorphic HLA alleles, thereby opening up more
possibilities for designing precision medicine strategies for more complex and
difficult-to-treat tumors.
The movie begins by showing the 10LH CAR :
PHOX2B–HLA-A*24:02 complex. The heavy and light chains of the 10LH CAR are
colored in purple and green, respectively. The peptide is shown as blue sticks
and the HLA is colored in gray. The structure is rotated by 180° and then zooms
into the prominent peptide selectivity filter which bridges elements from all
three components of the molecular complex. The key HLA residue (Q72) is shown
in orange, the key peptide residue (R6) in blue, and key CAR residues in pink (D232
- heavy chain) and green (W88 - light chain). Hydrogen bonds are shown in black
dashed lines and a cation-π interaction is shown as a yellow dashed line.
The movie then zooms out to show the HLA framework residues along the a1 helix
of the HLA. It zooms into the hydrogen bonds between these framework residues
and 10LH CDRs. The movie then zooms out again to show the framework residues
along the a2 helix of the HLA. Again, hydrogen bonds are shown when zoomed into
specific contacts. The movie ends by showing the whole complex again. Credit:
Nikolaos Sgourakis
"If CARs are not matched properly to target the specific alleles
associated with certain cancers, there is a risk of inducing toxicity without
providing any therapeutic benefit," said senior author Nikolaos G.
Sgourakis, Ph.D., Associate Professor in the Center for Computational and
Genomic Medicine at CHOP. "By looking at their 3D complex structures, we
can use these findings to design CARs that are able to target multiple HLAs and
increase the efficiency of therapeutic design."
Earlier CAR therapies could only target cancer-specific antigens on the
surface of tumor cells, and most of
these reside within the cells. However, researchers have found that these
previously inaccessible targets are eventually degraded into peptides, which
can be expressed on the surface like "barcodes" and then targeted
by therapy. Even then,
with so much variability in the alleles of the HLA, CAR therapies might only be
able to help a fraction of patients with tumors, depending on which peptides
are expressed on the surface of a tumor cell.
Since HLAs have more than 25,000 potentially mutated alleles, going through
them one-by-one to find potential targets and design associated CAR therapies
is far too complex a task.
In this study, however, researchers used a combination of biochemical
binding assays, molecular dynamics
simulations and structural and functional analyses to
determine that certain classes of HLAs are cross-reactive, meaning that
different antigens can be similarly recognized by PC-CAR therapy. In other
words, while the peptide "barcodes" may have significant variability,
the "backbone" of these HLAs is similar enough to be recognized by
these therapies.
This work was carried out by a group of undergraduate and graduate students
from the University of Pennsylvania and CHOP senior scientists from the
Sgourakis Lab.
CHOP has been a pioneer in the development of PC-CARs. Senior study
co-author John M. Maris, MD, pediatric oncologist and Giulio D'Angio Chair in
Neuroblastoma Research at CHOP, concurrently published an updated paper in the
journal Nature about the development and effectiveness of
PC-CARs, and patients are currently being recruited for clinical trials based
on their HLA genotypes to further explore the effectiveness of PC-CARs for
treating rare and complex forms of cancer.
"For any CAR T cell therapy to be both safe and effective, one must
find 'targets' for the T cells to find the tumor. PC-CAR T cells hone to very
specific targets that are only on cancer cells and not on normal healthy
cells," Maris said.
"This study essentially provides us with a blueprint for how to integrate new knowledge about the structural biology of HLAs as well as PC-CARs in this exciting field of new options for treating challenging cancers."
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