SARS-CoV-2 and other
coronaviruses pose major threats to global
health, yet computational efforts to understand them have largely
overlooked the process of budding, a key part of the coronavirus life
cycle. When expressed together, coronavirus M and E proteins are sufficient
to facilitate budding into the ER-Golgi intermediate compartment (ERGIC).
To help elucidate budding, we ran atomistic molecular dynamics (MD)
simulations using the Feig laboratory’s refined structural
models of the SARS-CoV-2 M protein dimer and E protein pentamer. Our
MD simulations consisted of M protein dimers and E protein pentamers
in patches of membrane. By examining where these proteins induced
membrane curvature
in silico
, we obtained insights
around how the budding process may occur. Multiple M protein dimers
acted together to induce global membrane curvature through protein–lipid
interactions while E protein pentamers kept the membrane planar. These
results could eventually help guide development of antiviral therapeutics
that inhibit coronavirus budding.
Gene therapy has demonstrated enormous potential for
changing how
we combat disease. By directly engineering the genetic composition
of cells, it provides a broad range of options for improving human
health. Adeno-associated viruses (AAVs) represent a leading gene therapy
vector and are expected to address a wide range of conditions in the
coming decade. Three AAV therapies have already been approved by the
FDA to treat Leber’s congenital amaurosis, spinal muscular
atrophy, and hemophilia B. Yet these therapies cost around $850,000,
$2,100,000, and $3,500,000, respectively. Such prices limit the broad
applicability of AAV gene therapy and make it inaccessible to most
patients. Much of this problem arises from the high manufacturing
costs of AAVs. At the same time, the field of synthetic biology has
grown rapidly and has displayed a special aptitude for addressing
biomanufacturing problems. Here, we discuss emerging efforts to apply
synthetic biology design to decrease the price of AAV production,
and we propose that such efforts could play a major role in making
gene therapy much more widely accessible.
Synthetic biology centers on the design and modular assembly of biological parts so as to construct artificial biological systems. Over the past decade, synthetic biology has blossomed into a highly productive field, yielding advances in diverse areas such as neuroscience, cell-based therapies, and chemical manufacturing. Similarly, the field of gene therapy has made enormous strides both in proof-of-concept studies and in the clinical setting. One viral vector of increasing interest for gene therapy is the adenovirus (Ad). A major part of the Ad's increasing momentum comes from synthetic biology approaches to Ad engineering. Convergence of gene therapy and synthetic biology has enhanced Ad vectors by mitigating Ad toxicity in vivo, providing precise Ad tropisms, and incorporating genetic circuits to make smart therapies which adapt to environmental stimuli. Synthetic biology engineering of Ad vectors may lead to superior gene delivery and editing platforms which could find applications in a wide range of therapeutic contexts.
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