Efficient engineering of human auricular cartilage through mesenchymal stem cell chaperoning.

A major challenge to the clinical translation of tissue-engineered ear scaffolds for ear reconstruction is the limited auricular chondrocyte (hAuC) yield available from patients. Starting with a relatively small number of chondrocytes in culture results in dedifferentiation and loss of phenotype with subsequent expansion. To significantly decrease the number of chondrocytes required for human elastic cartilage engineering, we co-cultured human mesenchymal stem cells (hMSCs) with HAuCs to promote healthy elastic cartilage formation.

Mitochondrial Dysfunction Is a Driver of SP-2509 Drug Resistance in Ewing Sarcoma.

Unlabelled: Expression of the fusion oncoprotein EWS/FLI causes Ewing sarcoma, an aggressive pediatric tumor characterized by widespread epigenetic deregulation. These epigenetic changes are targeted by novel lysine-specific demethylase-1 (LSD1) inhibitors, which are currently in early-phase clinical trials. Single-agent-targeted therapy often induces resistance, and successful clinical development requires knowledge of resistance mechanisms, enabling the design of effective combination strategies.

Inferior Oblique Entrapment After Orbital Fracture With Transection and Repair.

Extraocular muscle (EOM) entrapment with resulting reduction in motility and diplopia is a known complication of orbital fractures. Less commonly, transection of the EOMs due to trauma, iatrogenic injury, or intentional myotomy may lead to persistent diplopia. The inferior oblique (IO) is often encountered during orbital surgery along the medial wall and floor, and may be disinserted to aid in visualization.

Rapid profiling of G2 phase to mitosis progression by flow cytometry in asynchronous cells.

The precise control of the cell cycle G2 phase to Mitosis (M phase) transition is central for cell fate determination. The commonly used methods for assessing G2 to M phase progression are based on synchronizing cells and involve perturbation of the natural cell cycle progression. Additionally, these methods are often time-consuming and labor-intensive.

Radioisotope-Based Protocol for Determination of Central Carbon Metabolism in T Cells.

T lymphocytes are the major components of the adaptive immune system. It's been known that T cells are able to engage a diverse range of metabolic programs to meet the metabolic demands during their life cycle from early development, activation to functional differentiation. Central carbon metabolic pathways provide energy, reducing power, and biosynthetic precursors to support T cell homeostasis, proliferation, and immune functions.

A Metabolism Toolbox for CAR T Therapy.

The adoptive transfer of T cells expressing chimeric antigen receptors (CARs) through genetic engineering is one of the most promising new therapies for treating cancer patients. A robust CAR T cell-mediated anti-tumor response requires the coordination of nutrient and energy supplies with CAR T cell expansion and function. However, the high metabolic demands of tumor cells compromise the function of CAR T cells by competing for nutrients within the tumor microenvironment (TME).

Phosphorylation of CDC25C by AMP-activated protein kinase mediates a metabolic checkpoint during cell-cycle G/M-phase transition.

From unicellular to multicellular organisms, cell-cycle progression is tightly coupled to biosynthetic and bioenergetic demands. Accumulating evidence has demonstrated the G/S-phase transition as a key checkpoint where cells respond to their metabolic status and commit to replicating the genome. However, the mechanism underlying the coordination of metabolism and the G/M-phase transition in mammalian cells remains unclear.

MYC and HIF in shaping immune response and immune metabolism.

Upon antigen stimulation, quiescent naive T cells undergo a phase of cell mass accumulation followed by cell cycle entry, clonal expansion, differentiation into functional subsets and back again to a quiescent state as they develop into memory cells. The transitions between these distinct cellular states place unique metabolic demands on energy, redox and biosynthesis. To fulfill these demands, T cells switch back and forth between their primary catabolic pathways.

A thymine tetrad assembly templated from thymidylic acid.

A template tetra-coupled with thymidylic acid through a phosphate linkage was characterized in methanol for emergent properties of nucleobase tetrad formation. Intramolecular hydrogen bonded base pairing in the absence of a cation was indicated for the thymidylic acid species supporting a monomeric template-assembled structure. Thus, an initial report of a stabilized individual thymine tetrad assembly is presented here.

Synthesis of a single G-quartet platform in water.

For over 50 years the G-quartet has been a defining self-assembled structure in biology and non-covalent synthesis. It is shown here for the first time that the G-quartet is isolatable in water in the absence of stabilizing G-quartet stacking or cations through the construction of a phosphate-linked template-assembled synthetic G-quartet. Synthetic design has facilitated preservation of the guanine base, ribose sugar, and phosphate components with correct linkage chemistry relative to G-quadruplex DNA.

Ester hydrolysis by a histidine-containing cavitein.

We have used a template-assembled synthetic protein (TASP) to investigate catalytic function in ester hydrolysis. A histidine-containing cavitein has been found to catalyze ester hydrolysis with a rate increase of 18 times that of background.

A template-assembled synthetic U-quadruplex.

Fo(u)r U: A lipophilic cavitand with four dinucleoside (uridine) residues has been synthesized and characterized. NMR spectroscopy evidence suggests the self-assembly of a U-quadruplex by the uracil nucleobases in organic solution under ambient conditions.

Monomer-dimer control and crystal engineering in TASPs.

We have reported a template assembled synthetic protein (cavitein Q4) as an unexpected dimer in the solid state and as a monomer-dimer equilibrium in solution. We have since reported an ability to bias a cavitein's monomer-dimer equilibrium in solution by sequence design involving histidine metal chelation or disulfide incorporation. However, little remains known about the forces contributing to dimeric cavitein crystal nucleation and lattice stabilization.

Conformationally constrained sequence designs to bias monomer-dimer equilibriums in TASP systems.

We have designed template-assembled synthetic proteins (TASPs) with the intent of controlling their oligomeric state by stabilizing specific helical tertiary structures via histidine metal ion chelation or disulfide incorporation. In solution, cavitein Q4 was previously determined to interconvert between a four-helix bundle monomer and an eight-helix bundle dimer. In this paper, we show that judicious mutation of cavitein Q4 can stabilize either the monomeric parallel four-helix bundle or the dimeric antiparallel eight-helix bundle structure.

Synthesis and characterization of a template-assembled synthetic U-quartet.

A lipophilic cavitand containing four triazole-linked uridine residues has been synthesized and characterized. Spectral evidence suggests a quartet arrangement of the uracil residues at both ambient and low temperatures. Treatment of the compound with Sr(2+) yields a homodimeric complex as evidenced by NMR spectroscopy.

The restoration of lumbar intervertebral disc load distribution: a comparison of three nucleus replacement technologies.

Study Design: A validated L3-L4 nonlinear finite element model was used to evaluate strain and pressure in the surrounding structures for 4 nucleus replacement technologies.

Objective: The objective of the current study was to compare subsidence and anular damage potential between 4 current nucleus replacement technologies. It was hypothesized that a fully conforming nucleus replacement would minimize the risk of both subsidence and anular damage.

Economic impact of improving outcomes of lumbar discectomy.

Background: Lumbar discectomy is usually a successful operation with a relatively low cost. Potential adjunctive procedures, such as repairing the anulus fibrosus or nucleus replacements, necessitate a cost-benefit analysis.

Purpose: This economic analysis was performed to understand the potential value of advanced implantable technologies designed to improve outcomes after discectomy.

Cation-complexation behavior of template-assembled synthetic G-quartets.

We report the preparation and solution study of a set of template-assembled synthetic G-quartets (TASQs) bound to different cations. These G-quartet baskets effectively extract cations of different sizes and valencies. They form isolated G-quartets with small cations such as Na+ and Sr(2+), and dimeric assemblies with larger cations such as Cs+.

Nucleus replacement with the DASCOR disc arthroplasty device: interim two-year efficacy and safety results from two prospective, non-randomized multicenter European studies.

Study Design: A prospective, nonrandomized multicenter study of lumbar disc nucleus replacement using the DASCOR Disc Arthroplasty Device. An interim analysis of clinical results is presented, obtained from European patients enrolled in 2 studies.

Objective: To determine the safety and efficacy of the DASCOR Device for the treatment of symptomatic single-level degenerative disc disease (DDD).

X-ray crystal analysis of a TASP: structural insights of a cavitein dimer.

Cavitein Q4 is a template assembled synthetic protein designed for X-ray crystallographic analysis. It is based on a previous monomeric helical bundle cavitein (N1GG) that consists of four identical parallel helical peptides. Crystals that were grown in the presence of bromide ions were used to solve the initial phases via single-wavelength anomalous dispersion (SAD).

An investigation into the native-like properties of de novo designed cavitand-based four-helix bundle proteins.

We investigated the hydrophobic packing of two previously designed caviteins, LG2 and LG3, which differ by one Gly in the linker regions between the peptide sequence and the cavitand scaffold. We sought to diminish the putative native-like properties of LG2 and LG3, and see if we could diagnose a change in the conformational specificity of the hydrophobic core. We replaced the leucine residues with norleucine residues at the hydrophobic positions in LG2 and LG3, to create NG2 and NG3, respectively.