Your search keyword '"Blainey, Paul"' showing total 14 results

1. Multiplexed enrichment and genomic profiling of peripheral blood cells reveal subset-specific immune signatures.

Author

Reyes M, Vickers D, Billman K, Eisenhaure T, Hoover P, Browne EP, Rao DA, Hacohen N, and Blainey PC

Subjects

Humans, Lipopolysaccharide Receptors metabolism, Lupus Erythematosus, Systemic blood, RNA-Seq methods, Transcriptome, Flow Cytometry methods, Lupus Erythematosus, Systemic genetics, Lymphocytes, Microfluidics instrumentation, Microfluidics methods, Monocytes, Single-Cell Analysis methods

Abstract

Specialized immune cell subsets are involved in autoimmune disease, cancer immunity, and infectious disease through a diverse range of functions mediated by overlapping pathways and signals. However, subset-specific responses may not be detectable in analyses of whole blood samples, and no efficient approach for profiling cell subsets at high throughput from small samples is available. We present a low-input microfluidic system for sorting immune cells into subsets and profiling their gene expression. We validate the system's technical performance against standard subset isolation and library construction protocols and demonstrate the importance of subset-specific profiling through in vitro stimulation experiments. We show the ability of this integrated platform to identify subset-specific disease signatures by profiling four immune cell subsets in blood from patients with systemic lupus erythematosus (SLE) and matched control subjects. The platform has the potential to make multiplexed subset-specific analysis routine in many research laboratories and clinical settings.

Published

2019

2. Microfluidic-based mini-metagenomics enables discovery of novel microbial lineages from complex environmental samples.

Author

Yu FB, Blainey PC, Schulz F, Woyke T, Horowitz MA, and Quake SR

Subjects

Computational Biology methods, United States, Hot Springs microbiology, Lab-On-A-Chip Devices, Metagenomics instrumentation, Metagenomics methods, Microfluidics instrumentation, Microfluidics methods

Abstract

Metagenomics and single-cell genomics have enabled genome discovery from unknown branches of life. However, extracting novel genomes from complex mixtures of metagenomic data can still be challenging and represents an ill-posed problem which is generally approached with ad hoc methods. Here we present a microfluidic-based mini-metagenomic method which offers a statistically rigorous approach to extract novel microbial genomes while preserving single-cell resolution. We used this approach to analyze two hot spring samples from Yellowstone National Park and extracted 29 new genomes, including three deeply branching lineages. The single-cell resolution enabled accurate quantification of genome function and abundance, down to 1% in relative abundance. Our analyses of genome level SNP distributions also revealed low to moderate environmental selection. The scale, resolution, and statistical power of microfluidic-based mini-metagenomics make it a powerful tool to dissect the genomic structure of microbial communities while effectively preserving the fundamental unit of biology, the single cell.

Published

2017

3. High-throughput automated microfluidic sample preparation for accurate microbial genomics.

Author

Kim S, De Jonghe J, Kulesa AB, Feldman D, Vatanen T, Bhattacharyya RP, Berdy B, Gomez J, Nolan J, Epstein S, and Blainey PC

Subjects

Bacterial Infections diagnosis, Bacterial Infections microbiology, Drug Resistance, Microbial genetics, Environmental Monitoring instrumentation, Environmental Monitoring methods, Gene Library, Genomics instrumentation, High-Throughput Nucleotide Sequencing, High-Throughput Screening Assays instrumentation, Humans, Lab-On-A-Chip Devices, Microfluidics instrumentation, Mycobacterium tuberculosis genetics, Mycobacterium tuberculosis isolation & purification, Oligonucleotide Array Sequence Analysis, Polymorphism, Single Nucleotide genetics, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa isolation & purification, Soil Microbiology, Whole Genome Sequencing instrumentation, Genome, Bacterial genetics, Genomics methods, High-Throughput Screening Assays methods, Microfluidics methods, Whole Genome Sequencing methods

Abstract

Low-cost shotgun DNA sequencing is transforming the microbial sciences. Sequencing instruments are so effective that sample preparation is now the key limiting factor. Here, we introduce a microfluidic sample preparation platform that integrates the key steps in cells to sequence library sample preparation for up to 96 samples and reduces DNA input requirements 100-fold while maintaining or improving data quality. The general-purpose microarchitecture we demonstrate supports workflows with arbitrary numbers of reaction and clean-up or capture steps. By reducing the sample quantity requirements, we enabled low-input (∼10,000 cells) whole-genome shotgun (WGS) sequencing of Mycobacterium tuberculosis and soil micro-colonies with superior results. We also leveraged the enhanced throughput to sequence ∼400 clinical Pseudomonas aeruginosa libraries and demonstrate excellent single-nucleotide polymorphism detection performance that explained phenotypically observed antibiotic resistance. Fully-integrated lab-on-chip sample preparation overcomes technical barriers to enable broader deployment of genomics across many basic research and translational applications., Competing Interests: The Broad Institute and MIT may seek to file for intellectual property on and/or commercialize aspects of this work. J.D.J., A.B.K., D.F., T.V., R.P.B., B.B., J.G., J.N. and S.E. declare no competing interests.

Published

2017

4. Virtual microfluidics for digital quantification and single-cell sequencing.

Author

Xu L, Brito IL, Alm EJ, and Blainey PC

Subjects

DNA Contamination, Electronic Data Processing, Escherichia coli genetics, Hydrogels chemistry, Microscopy, Fluorescence, Staphylococcus aureus genetics, User-Computer Interface, Workflow, Genome, Bacterial, High-Throughput Nucleotide Sequencing methods, Microfluidics methods, Nucleic Acid Amplification Techniques methods, Sequence Analysis, DNA methods, Single-Cell Analysis methods

Abstract

We have developed hydrogel-based virtual microfluidics as a simple and robust alternative to complex engineered microfluidic systems for the compartmentalization of nucleic acid amplification reactions. We applied in-gel digital multiple displacement amplification (dMDA) to purified DNA templates, cultured bacterial cells and human microbiome samples in the virtual microfluidics system, and demonstrated whole-genome sequencing of single-cell MDA products with excellent coverage uniformity and markedly reduced chimerism compared with products of liquid MDA reactions.

Published

2016

5. Optofluidic Single-Cell Genome Amplification of Sub-micron Bacteria in the Ocean Subsurface.

Author

Landry, Zachary, Vergin, Kevin, Mannenbach, Christopher, Block, Stephen, Yang, Qiao, Blainey, Paul, Carlson, Craig, and Giovannoni, Stephen

Subjects

E01-9C-26, bermuda-atlantic time-series, marine microbiology, microfluidics, optofluidics, single-cell genomics

Abstract

Optofluidic single-cell genome amplification was used to obtain genome sequences from sub-micron cells collected from the euphotic and mesopelagic zones of the northwestern Sargasso Sea. Plankton cells were visually selected and manually sorted with an optical trap, yielding 20 partial genome sequences representing seven bacterial phyla. Two organisms, E01-9C-26 (Gammaproteobacteria), represented by four single cell genomes, and Opi.OSU.00C, an uncharacterized Verrucomicrobia, were the first of their types retrieved by single cell genome sequencing and were studied in detail. Metagenomic data showed that E01-9C-26 is found throughout the dark ocean, while Opi.OSU.00C was observed to bloom transiently in the nutrient-depleted euphotic zone of the late spring and early summer. The E01-9C-26 genomes had an estimated size of 4.76-5.05 Mbps, and contained O and W-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes. Metabolic reconstruction indicated E01-9C-26 are likely versatile methylotrophs capable of scavenging C1 compounds, methylated compounds, reduced sulfur compounds, and a wide range of amines, including D-amino acids. The genome sequences identified E01-9C-26 as a source of O and W-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes, but are of unknown function. In contrast, Opi.OSU.00C genomes encode genes for catabolizing carbohydrate compounds normally associated with eukaryotic phytoplankton. This exploration of optofluidics showed that it was effective for retrieving diverse single-cell bacterioplankton genomes and has potential advantages in microbiology applications that require working with small sample volumes or targeting cells by their morphology.

Published

2018

6. Microfluidic-based mini-metagenomics enables discovery of novel microbial lineages from complex environmental samples.

Author

Yu, Feiqiao Brian, Blainey, Paul C, Schulz, Frederik, Woyke, Tanja, Horowitz, Mark A, and Quake, Stephen R

Subjects

Microfluidics, Computational Biology, Hot Springs, United States, Metagenomics, Lab-On-A-Chip Devices, Yellowstone National Park, bining, computational biology, infectious disease, metagenomics, microbiology, microfluidics, mini-metagenomics, novel phylogenetic groups, systems biology, Genetics, Biotechnology, Human Genome, Bioengineering, Generic health relevance, Biochemistry and Cell Biology

Abstract

Metagenomics and single-cell genomics have enabled genome discovery from unknown branches of life. However, extracting novel genomes from complex mixtures of metagenomic data can still be challenging and represents an ill-posed problem which is generally approached with ad hoc methods. Here we present a microfluidic-based mini-metagenomic method which offers a statistically rigorous approach to extract novel microbial genomes while preserving single-cell resolution. We used this approach to analyze two hot spring samples from Yellowstone National Park and extracted 29 new genomes, including three deeply branching lineages. The single-cell resolution enabled accurate quantification of genome function and abundance, down to 1% in relative abundance. Our analyses of genome level SNP distributions also revealed low to moderate environmental selection. The scale, resolution, and statistical power of microfluidic-based mini-metagenomics make it a powerful tool to dissect the genomic structure of microbial communities while effectively preserving the fundamental unit of biology, the single cell.

Published

2017

7. The future of antibiotics begins with discovering new combinations.

Author

Zhu, Meilin, Tse, Megan W., Weller, Juliane, Chen, Julie, and Blainey, Paul C.

Subjects

ANTIBIOTICS, MYCOBACTERIAL diseases, BACTERIAL diseases, DRUG resistance in bacteria, VIRUS diseases, MULTIDRUG resistance in bacteria, ANTIVIRAL agents

Abstract

Antibiotic resistance is a worldwide and growing clinical problem. With limited drug development in the antibacterial space, combination therapy has emerged as a promising strategy to combat multidrug‐resistant bacteria. Antibacterial combinations can improve antibiotic efficacy and suppress antibacterial resistance through independent, synergistic, or even antagonistic activities. Combination therapies are famously used to treat viral and mycobacterial infections and cancer. However, antibacterial combinations are only now emerging as a common treatment strategy for other bacterial infections owing to challenges in their discovery, development, regulatory approval, and commercial/clinical deployment. Here, we focus on discovery—where the sheer scale of combinatorial chemical spaces represents a significant challenge—and discuss how combination therapy can impact the treatment of bacterial infections. Despite these challenges, recent advancements, including new in silico methods, theoretical frameworks, and microfluidic platforms, are poised to identify the new and efficacious antibacterial combinations needed to revitalize the antibacterial drug pipeline. [ABSTRACT FROM AUTHOR]

Published

2021

8. Optofluidic Single-Cell Genome Amplification of Sub-micron Bacteria in the Ocean Subsurface.

Author

Landry, Zachary C., Vergin, Kevin, Mannenbach, Christopher, Block, Stephen, Qiao Yang, Blainey, Paul, Carlson, Craig, and Giovannoni, Stephen

Subjects

OPTOFLUIDICS, GENOMES

Abstract

Optofluidic single-cell genome amplification was used to obtain genome sequences from sub-micron cells collected from the euphotic and mesopelagic zones of the northwestern Sargasso Sea. Plankton cells were visually selected and manually sorted with an optical trap, yielding 20 partial genome sequences representing seven bacterial phyla. Two organisms, E01-9C-26 (Gammaproteobacteria), represented by four single cell genomes, and Opi.OSU.00C, an uncharacterized Verrucomicrobia, were the first of their types retrieved by single cell genome sequencing and were studied in detail. Metagenomic data showed that E01-9C-26 is found throughout the dark ocean, while Opi.OSU.00C was observed to bloom transiently in the nutrient-depleted euphotic zone of the late spring and early summer. The E01-9C-26 genomes had an estimated size of 4.76-5.05 Mbps, and contained "O" and "W"-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes. Metabolic reconstruction indicated E01-9C-26 are likely versatile methylotrophs capable of scavenging C1 compounds, methylated compounds, reduced sulfur compounds, and a wide range of amines, including D-amino acids. The genome sequences identified E01-9C-26 as a source of "O" and "W"-typemonooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes, but are of unknown function. In contrast, Opi.OSU.00C genomes encode genes for catabolizing carbohydrate compounds normally associated with eukaryotic phytoplankton. This exploration of optofluidics showed that it was effective for retrieving diverse single-cell bacterioplankton genomes and has potential advantages in microbiology applications that require working with small sample volumes or targeting cells by their morphology. [ABSTRACT FROM AUTHOR]

Published

2018

9. Laser microdissection of the alveolar duct enables single-cell genomic analysis.

Author

Bennett, Robert D., Ysasi, Alexandra B., Belle, Janeil M., Mentzer, Steven J., Wagner, Willi L., Konerding, Moritz A., Blainey, Paul C., and Pyne, Saumyadipta

Subjects

MICRODISSECTION, MICROFLUIDICS, TISSUES, LUNGS, MICROSCOPY

Abstract

Complex tissues such as the lung are composed of structural hierarchies such as alveoli, alveolar ducts, and lobules. Some structural units, such as the alveolar duct, appear to participate in tissue repair as well as the development of bronchioalveolar carcinoma. Here, we demonstrate an approach to conduct laser microdissection of the lung alveolar duct for single-cell PCR analysis. Our approach involved three steps. (1) The initial preparation used mechanical sectioning of the lung tissue with sufficient thickness to encompass the structure of interest. In the case of the alveolar duct, the precision-cut lung slices were 200μm thick; the slices were processed using near-physiologic conditions to preserve the state of viable cells. (2)The lung slices were examined by transmission light microscopy to target the alveolar duct. The air-filled lung was sufficiently accessible by light microscopy that counterstains or fluorescent labels were unnecessary to identify the alveolar duct. (3) The enzymatic and microfluidic isolation of single cells allowed for the harvest of as few as several thousand cells for PCR analysis. Microfluidics based arrays were used to measure the expression of selected marker genes in individual cells to characterize different cell populations. Preliminary work suggests the unique value of this approach to understand the intra- and intercellular interactions within the regenerating alveolar duct. [ABSTRACT FROM AUTHOR]

Published

2014

10. The future is now: single-cell genomics of bacteria and archaea.

Author

Blainey, Paul C.

Subjects

*GENOMICS, *BACTERIA, *ARCHAEBACTERIA, *MICROORGANISMS, *ROAD maps, *MICROENCAPSULATION, *MICROFLUIDICS

Abstract

Interest in the expanding catalog of uncultivated microorganisms, increasing recognition of heterogeneity among seemingly similar cells, and technological advances in whole-genome amplification and single-cell manipulation are driving considerable progress in single-cell genomics. Here, the spectrum of applications for single-cell genomics, key advances in the development of the field, and emerging methodology for single-cell genome sequencing are reviewed by example with attention to the diversity of approaches and their unique characteristics. Experimental strategies transcending specific methodologies are identified and organized as a road map for future studies in single-cell genomics of environmental microorganisms. Over the next decade, increasingly powerful tools for single-cell genome sequencing and analysis will play key roles in accessing the genomes of uncultivated organisms, determining the basis of microbial community functions, and fundamental aspects of microbial population biology. [ABSTRACT FROM AUTHOR]

Published

2013

11. Optofluidic Single-Cell Genome Amplification of Sub-micron Bacteria in the Ocean Subsurface

Author

Zachary C. Landry, Kevin Vergin, Christopher Mannenbach, Stephen Block, Qiao Yang, Paul Blainey, Craig Carlson, Stephen Giovannoni, Massachusetts Institute of Technology. Department of Biological Engineering, and Blainey, Paul C

Subjects

0301 basic medicine, Microbiology (medical), 030106 microbiology, lcsh:QR1-502, microfluidics, single-cellgenomics, E01-9C-26, marine microbiology, optofluidics, bermuda-atlantic, time-series, Computational biology, Biology, ENCODE, Microbiology, Genome, lcsh:Microbiology, DNA sequencing, 03 medical and health sciences, Gammaproteobacteria, Gene, bermuda-atlantic time-series, single-cell genomics, Verrucomicrobia, Bacterioplankton, biology.organism_classification, 030104 developmental biology, Metagenomics

Abstract

Optofluidic single-cell genome amplification was used to obtain genome sequences from sub-micron cells collected from the euphotic and mesopelagic zones of the northwestern Sargasso Sea. Plankton cells were visually selected and manually sorted with an optical trap, yielding 20 partial genome sequences representing seven bacterial phyla. Two organisms, E01-9C-26 (Gammaproteobacteria), represented by four single cell genomes, and Opi.OSU.00C, an uncharacterized Verrucomicrobia, were the first of their types retrieved by single cell genome sequencing and were studied in detail. Metagenomic data showed that E01-9C-26 is found throughout the dark ocean, while Opi.OSU.00C was observed to bloom transiently in the nutrient-depleted euphotic zone of the late spring and early summer. The E01-9C-26 genomes had an estimated size of 4.76–5.05 Mbps, and contained “O” and “W”-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes. Metabolic reconstruction indicated E01-9C-26 are likely versatile methylotrophs capable of scavenging C1 compounds, methylated compounds, reduced sulfur compounds, and a wide range of amines, including D-amino acids. The genome sequences identified E01-9C-26 as a source of “O” and “W”-type monooxygenase genes related to methane and ammonium monooxygenases that were previously reported from ocean metagenomes, but are of unknown function. In contrast, Opi.OSU.00C genomes encode genes for catabolizing carbohydrate compounds normally associated with eukaryotic phytoplankton. This exploration of optofluidics showed that it was effective for retrieving diverse single-cell bacterioplankton genomes and has potential advantages in microbiology applications that require working with small sample volumes or targeting cells by their morphology., Frontiers in Microbiology, 9, ISSN:1664-302X

Published

2017

12. Microfluidic-based mini-metagenomics enables discovery of novel microbial lineages from complex environmental samples

Author

Frederik Schulz, Paul C. Blainey, Stephen R. Quake, Tanja Woyke, Feiqiao Brian Yu, Mark Horowitz, Massachusetts Institute of Technology. Department of Biological Engineering, and Blainey, Paul C

Subjects

Nonsynonymous substitution, 0301 basic medicine, Ecological selection, Microfluidics, bining, Yellowstone National Park, Genome, Hot Springs, Lab-On-A-Chip Devices, mini-metagenomics, Taxonomic rank, Biology (General), Genetics, Microbiology and Infectious Disease, Sample complexity, General Neuroscience, systems biology, General Medicine, Medicine, Research Article, Computational and Systems Biology, Biotechnology, Microbial Genomes, QH301-705.5, Science, infectious disease, Systems biology, 030106 microbiology, microfluidics, Bioengineering, Genomics, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, metagenomics, General Immunology and Microbiology, microbiology, Human Genome, Computational Biology, United States, 030104 developmental biology, novel phylogenetic groups, Metagenomics, Other, Generic health relevance, Biochemistry and Cell Biology

Abstract

Metagenomics and single-cell genomics have enabled the discovery of many new genomes from previously unknown branches of life. However, extracting novel genomes from complex mixtures of metagenomic data can still be challenging and in many respects represents an ill-posed problem which is generally approached with ad hoc methods. Here we present a microfluidic-based mini-metagenomic method which offers a statistically rigorous approach to extract novel microbial genomes from complex samples. In addition, by generating 96 sub-samples from each environmental sample, this method maintains high throughput, reduces sample complexity, and preserves single-cell resolution. We used this approach to analyze two hot spring samples from Yellowstone National Park and extracted 29 new genomes larger than 0.5 Mbps. These genomes represent novel lineages at different taxonomic levels, including three deeply branching lineages. Functional analysis revealed that these organisms utilize diverse pathways for energy metabolism. The resolution of this mini-metagenomic method enabled accurate quantification of genome abundance, even for genomes less than 1% in relative abundance. Our analyses also revealed a wide range of genome level single nucleotide polymorphism (SNP) distributions with nonsynonymous to synonymous ratio indicative of low to moderate environmental selection. The scale, resolution, and statistical power of microfluidic-based mini-metagenomic make it a powerful tool to dissect the genomic structure microbial communities while effectively preserving the fundamental unit of biology, the single cell.

Published

2017

13. High-throughput automated microfluidic sample preparation for accurate microbial genomics

Author

David Feldman, Tommi Vatanen, James Gomez, Slava S. Epstein, Joachim De Jonghe, Soohong Kim, Brittany Berdy, Roby P. Bhattacharyya, Paul C. Blainey, Jill Nolan, Anthony Kulesa, Broad Institute, University of Cambridge, Department of Computer Science, Massachusetts General Hospital, Northeastern University, Aalto-yliopisto, Aalto University, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Physics, Kim, Soohong, Kulesa, Anthony Benjamin, Feldman, David, and Blainey, Paul C

Subjects

0301 basic medicine, Science, Microfluidics, 030106 microbiology, General Physics and Astronomy, Sample (statistics), Genomics, Nanotechnology, Computational biology, Biology, Polymorphism, Single Nucleotide, Article, General Biochemistry, Genetics and Molecular Biology, DNA sequencing, 03 medical and health sciences, Lab-On-A-Chip Devices, High-Throughput Screening Assays, Humans, Genomic library, Sample preparation, Throughput (business), Soil Microbiology, Gene Library, Oligonucleotide Array Sequence Analysis, ta113, Whole genome sequencing, Multidisciplinary, Whole Genome Sequencing, High-Throughput Nucleotide Sequencing, Drug Resistance, Microbial, Bacterial Infections, Mycobacterium tuberculosis, General Chemistry, 030104 developmental biology, Pseudomonas aeruginosa, Genome, Bacterial, Environmental Monitoring

Abstract

Low-cost shotgun DNA sequencing is transforming the microbial sciences. Sequencing instruments are so effective that sample preparation is now the key limiting factor. Here, we introduce a microfluidic sample preparation platform that integrates the key steps in cells to sequence library sample preparation for up to 96 samples and reduces DNA input requirements 100-fold while maintaining or improving data quality. The general-purpose microarchitecture we demonstrate supports workflows with arbitrary numbers of reaction and clean-up or capture steps. By reducing the sample quantity requirements, we enabled low-input (∼10,000 cells) whole-genome shotgun (WGS) sequencing of Mycobacterium tuberculosis and soil micro-colonies with superior results. We also leveraged the enhanced throughput to sequence ∼400 clinical Pseudomonas aeruginosa libraries and demonstrate excellent single-nucleotide polymorphism detection performance that explained phenotypically observed antibiotic resistance. Fully-integrated lab-on-chip sample preparation overcomes technical barriers to enable broader deployment of genomics across many basic research and translational applications., Burroughs Wellcome Fund (Career Award at the Scientific Interface), David H. Koch Institute for Integrative Cancer Research at MIT (Startup Funds), United States. Department of Energy. Joint Genome Institute (Emerging Technologies Opportunity Program Award), National Science Foundation (U.S.). Graduate Research Fellowship Program (1308852)

Published

2017

14. Laser Microdissection of the Alveolar Duct Enables Single-Cell Genomic Analysis

Author

Saumyadipta Pyne, Willi L. Wagner, Paul C. Blainey, Steven J. Mentzer, Janeil Belle, Alexandra B. Ysasi, Robert D. Bennett, Moritz A. Konerding, Massachusetts Institute of Technology. Department of Biological Engineering, and Blainey, Paul C

Subjects

Pathology, medicine.medical_specialty, Cancer Research, Cell, microfluidics, regenerative medicine, alveolar duct, lcsh:RC254-282, Regenerative medicine, Alveolar duct, Single-cell analysis, Microscopy, medicine, single-cell analysis, Original Research, Laser capture microdissection, Lung, Chemistry, respiratory system, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, medicine.anatomical_structure, murine lung gene expression, Oncology, signaling network, laser microdissection, Lung tissue

Abstract

Complex tissues such as the lung are composed of structural hierarchies such as alveoli, alveolar ducts, and lobules. Some structural units, such as the alveolar duct, appear to participate in tissue repair as well as the development of bronchioalveolar carcinoma. Here, we demonstrate an approach to conduct laser microdissection of the lung alveolar duct for single-cell PCR analysis. Our approach involved three steps. The initial preparation used mechanical sectioning of the lung tissue with sufficient thickness to encompass the structure of interest. In the case of the alveolar duct, the precision-cut lung slices were 200µm thick; the slices were processed using near-physiologic conditions to preserve the state of viable cells. The lung slices were examined by transmission light microscopy to target the alveolar duct. The air-filled lung was sufficiently accessible by light microscopy that counterstains or fluorescent labels were unnecessary to identify the alveolar duct. The enzymatic and microfluidic isolation of single cells allowed for the harvest of as few as several thousand cells for PCR analysis. Microfluidics based arrays were used to measure the expression of selected marker genes in individual cells to characterize different cell populations. Preliminary work suggests the unique value of this approach to understand the intra- and intercellular interactions within the regenerating alveolar duct., National Institutes of Health (U.S.) (Grants HL94567 and CA009535)

Published

2014