Karl J. Lewis scite author profile

Tooth decay (dental caries) is a widespread human disease caused by microbial biofilms.Streptococcus mutans, a biofilm-former, has been consistently associated with severe childhood caries; however, how this bacterium is spatially organized with other microorganisms in the oral cavity to promote disease remains unknown. Using intact biofilms formed on teeth of toddlers affected by caries, we discovered a unique 3D rotund-shaped architecture composed of multiple species precisely arranged in a corona-like structure with an inner core ofS. mutansencompassed by outer layers of other bacteria. This architecture creates localized regions of acidic pH and acute enamel demineralization (caries) in a mixed-species biofilm model on human teeth, suggesting this highly ordered community as the causative agent. Notably, the construction of this architecture was found to be an active process initiated by production of an extracellular scaffold byS. mutansthat assembles the corona cell arrangement, encapsulating the pathogen core. In addition, this spatial patterning creates a protective barrier against antimicrobials while increasing bacterial acid fitness associated with the disease-causing state. Our data reveal a precise biogeography in a polymicrobial community associated with human caries that can modulate the pathogen positioning and virulence potential in situ, indicating that micron-scale spatial structure of the microbiome may mediate the function and outcome of host–pathogen interactions.

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Osteocyte calcium signals encode strain magnitude and loading frequency in vivo

Lewis

Frikha-Benayed

Louie

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Osteocytes are considered to be the major mechanosensory cells of bone, but how osteocytes in vivo process, perceive, and respond to mechanical loading remains poorly understood. Intracellular calcium (Ca) signaling resulting from mechanical stimulation has been widely studied in osteocytes in vitro and in bone explants, but has yet to be examined in vivo. This is achieved herein by using a three-point bending device which is capable of delivering well-defined mechanical loads to metatarsal bones of living mice while simultaneously monitoring the intracellular Ca responses of individual osteocytes by using a genetically encoded fluorescent Ca indicator. Osteocyte responses are imaged by using multiphoton fluorescence microscopy. We investigated the in vivo responses of osteocytes to strains ranging from 250 to 3,000 [Formula: see text] and frequencies from 0.5 to 2 Hz, which are characteristic of physiological conditions reported for bone. At all loading frequencies examined, the number of responding osteocytes increased strongly with applied strain magnitude. However, Ca intensity within responding osteocytes did not change significantly with physiological loading magnitudes. Our studies offer a glimpse into how these critical bone cells respond to mechanical load in vivo, as well as provide a technique to determine how the cells encode magnitude and frequency of loading.

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The Contribution of Bone and Cartilage to the Near-Infrared Spectrum of Osteochondral Tissue

et al. 2014

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Near-infrared (NIR) spectroscopy has been utilized to assess hyaline cartilage quality in human and animal osteochondral tissues. However, due to the lack of NIR signal from bone phosphate, and the relatively deep penetration depth of the radiation, the separate contributions of cartilage and bone to the spectral signatures have not been well defined. The objectives of the current study were 1) to improve the understanding of the contributions of bone and cartilage to NIR spectra acquired from osteochondral tissue, and 2) to assess the ability of this non-destructive method to predict cartilage thickness and modified Mankin grade of human tibial plateau articular cartilage. NIR spectra were acquired from samples of bovine bone and cartilage with varying thicknesses, and from twenty-two tibial plateaus harvested from patients undergoing knee replacement surgery. Spectra were recorded from regions of the tibial plateaus with varying degrees of degradation, and the cartilage thickness and modified Mankin grade of these regions were assessed histologically. Spectra from bone and cartilage samples of known thicknesses were investigated to identify spectral regions that were distinct for these two tissues. Univariate and multivariate linear regression methods were used to correlate modified Mankin grade and cartilage thickness with NIR spectral changes. The ratio of the NIR absorbances associated with water at 5270 and 7085 cm−1 were the best differentiator of cartilage and bone spectra. NIR prediction models for thickness and Mankin grade calculated using partial least squares regression were more accurate than univariate-based prediction models, with root mean square errors of cross validation of 0.42 mm (thickness) and 1.3 (modified Mankin grade), respectively. We conclude that NIR spectroscopy may be used to simultaneously assess articular cartilage thickness and modified Mankin grade, based in part on differences in spectral contributions from bone and cartilage.

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The importance of diversity, equity, and inclusion in orthopedic research

Alliston

Foucher

Frederick

et al. 2020

Journal Orthopaedic Research

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The mTORC2 Component Rictor Is Required for Load‐Induced Bone Formation in Late‐Stage Skeletal Cells

Lewis

Wright

et al. 2020

JBMR Plus

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Bone relies on mechanical cues to build and maintain tissue composition and architecture. Our understanding of bone cell mechanotransduction continues to evolve, with a few key signaling pathways emerging as vital. Wnt/β-catenin, for example, is essential for proper anabolic response to mechanical stimulation. One key complex that regulates β-catenin activity is the mammalian target of rapamycin complex 2 (mTORc2). mTORc2 is critical for actin cytoskeletal reorganization, an indispensable component in mechanotransduction in certain cell types. In this study, we probed the impact of the mTORc2 signaling pathway in osteocyte mechanotransduction by conditionally deleting the mTORc2 subunit Rictor in Dmp1-expressing cells of C57BL/6 mice. Conditional deletion of the Rictor was achieved using the Dmp1-Cre driver to recombine Rictor floxed alleles. Rictor mutants exhibited a decrease in skeletal properties, as measured by DXA, μCT, and mechanical testing, compared with Cre-negative floxed littermate controls. in vivo axial tibia loading conducted in adult mice revealed a deficiency in the osteogenic response to loading among Rictor mutants. Histological measurements of osteocyte morphology indicated fewer, shorter cell processes in Rictor mutants, which might explain the compromised response to mechanical stimulation. In summary, inhibition of the mTORc2 pathway in late osteoblasts/osteocytes leads to decreased bone mass and mechanically induced bone formation.

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Estrogen depletion on In vivo osteocyte calcium signaling responses to mechanical loading

Lewis

Cabahug‐Zuckerman

Boorman-Padgett

et al. 2021

Bone

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Expression of a Degradation-Resistant β-Catenin Mutant in Osteocytes Protects the Skeleton From Mechanodeprivation-Induced Bone Wasting

Bullock

Hoggatt

Horan

et al. 2019

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Mechanical stimulation is a key regulator of bone mass, maintenance, and turnover. Wnt signaling is a key regulator of mechanotransduction in bone, but the role of β-catenin-an intracellular signaling node in the canonical Wnt pathway-in disuse mechanotransduction is not defined. Using the β-catenin exon 3 flox (constitutively active [CA]) mouse model, in conjunction with a tamoxifen-inducible, osteocyte-selective Cre driver, we evaluated the effects of degradation-resistant β-catenin on bone properties during disuse. We hypothesized that if β-catenin plays an important role in Wnt-mediated osteoprotection, then artificial stabilization of β-catenin in osteocytes would protect the limbs from disuse-induced bone wasting. Two disuse models were tested: tail suspension, which models fluid shift, and botulinum-toxin (botox)-induced muscle paralysis, which models loss of muscle force. Tail suspension was associated with a significant loss of tibial bone mass and density, reduced architectural properties, and decreased bone formation indices in uninduced (control) mice, as assessed by dual-energy X-ray absorptiometry (DXA), micro-computed tomography (µCT), and histomorphometry. Activation of the βcatCA allele in tail-suspended mice resulted in little to no change in those properties; ie, these mice were protected from bone loss. Similar protective effects were observed among botox-treated mice when the βcatCA was activated. RNAseq analysis of altered gene regulation in tail-suspended mice yielded 35 genes, including Wnt11, Gli1, Nell1, Gdf5, and Pgf, which were significantly differentially regulated between tailsuspended β-catenin stabilized mice and tail-suspended nonstabilized mice. Our findings indicate that selectively targeting/ blocking of β-catenin degradation in bone cells could have therapeutic implications in mechanically induced bone disease.

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Osteocyte calcium signaling – A potential translator of mechanical load to mechanobiology

Lewis

2021

Bone

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Karl J. Lewis

Spatial mapping of polymicrobial communities reveals a precise biogeography associated with human dental caries

Osteocyte calcium signals encode strain magnitude and loading frequency in vivo

The Contribution of Bone and Cartilage to the Near-Infrared Spectrum of Osteochondral Tissue

The importance of diversity, equity, and inclusion in orthopedic research

The mTORC2 Component Rictor Is Required for Load‐Induced Bone Formation in Late‐Stage Skeletal Cells

Estrogen depletion on In vivo osteocyte calcium signaling responses to mechanical loading

Expression of a Degradation-Resistant β-Catenin Mutant in Osteocytes Protects the Skeleton From Mechanodeprivation-Induced Bone Wasting

Osteocyte calcium signaling – A potential translator of mechanical load to mechanobiology

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