Your search keyword '"Yelena Golubeva"' showing total 4 results

1. Collection and preparation of rodent embryonic samples for transcriptome study

Author

Yelena, Golubeva and David, Symer

Subjects

Gene Expression Profiling, Embryonic Development, Proteins, DNA, Embryo, Mammalian, Microarray Analysis, Mice, Pregnancy, Animals, Humans, RNA, Female, Transcriptome, Molecular Biology

Abstract

The need for large-scale collection of rodent embryos and individual embryonic tissues for genomic and proteomic studies requires modification of traditional practices of embryo necropsy. The sample intended for transcriptome study should be rapidly dissected and stabilized to preserve its molecular integrity. The retrieval of high-quality RNA, DNA, and proteins from the target tissue is crucial for informative molecular analysis (e.g., gene profiling on microarray platform). We present a reliable method of collection and preparation of rodent embryos for genomic studies supported by detailed protocols and RNA extraction results for different stages of mouse embryonic development.

Published

2013

2. Collection and Preparation of Rodent Embryonic Samples for Transcriptome Study

Author

Yelena Golubeva and David E. Symer

Subjects

Transcriptome, chemistry.chemical_compound, chemistry, Embryogenesis, RNA, Embryo, RNA extraction, Computational biology, Biology, Gene, Embryonic stem cell, Molecular biology, DNA

Abstract

The need for large-scale collection of rodent embryos and individual embryonic tissues for genomic and proteomic studies requires modification of traditional practices of embryo necropsy. The sample intended for transcriptome study should be rapidly dissected and stabilized to preserve its molecular integrity. The retrieval of high-quality RNA, DNA, and proteins from the target tissue is crucial for informative molecular analysis (e.g., gene profiling on microarray platform). We present a reliable method of collection and preparation of rodent embryos for genomic studies supported by detailed protocols and RNA extraction results for different stages of mouse embryonic development.

Published

2013

3. Optimizing Frozen Sample Preparation for Laser Microdissection: Assessment of CryoJane Tape-Transfer System®

Author

Lawrence R. Sternberg, Yelena Golubeva, and Roberta M. Smith

Subjects

Pathology, medicine.medical_specialty, Materials science, Histology, Laser cutting, Clinical Research Design, Preclinical Models, RNA Stability, Population, Cytometric Techniques, lcsh:Medicine, Dissection procedure, Laser Capture Microdissection, Toxicology, law.invention, Specimen Handling, Mice, law, Genome Analysis Tools, Molecular Cell Biology, medicine, Animals, education, lcsh:Science, Biology, Microdissection, Laser capture microdissection, Skin, education.field_of_study, Multidisciplinary, Laboratory glassware, lcsh:R, Genomics, DNA, Laser, Oncology, Liver, Medicine, RNA, lcsh:Q, RNA extraction, Genome Expression Analysis, Cytometry, Biomedical engineering, Research Article, Biotechnology

Abstract

Laser microdissection is an invaluable tool in medical research that facilitates collecting specific cell populations for molecular analysis. Diversity of research targets (e.g., cancerous and precancerous lesions in clinical and animal research, cell pellets, rodent embryos, etc.) and varied scientific objectives, however, present challenges toward establishing standard laser microdissection protocols. Sample preparation is crucial for quality RNA, DNA and protein retrieval, where it often determines the feasibility of a laser microdissection project. The majority of microdissection studies in clinical and animal model research are conducted on frozen tissues containing native nucleic acids, unmodified by fixation. However, the variable morphological quality of frozen sections from tissues containing fat, collagen or delicate cell structures can limit or prevent successful harvest of the desired cell population via laser dissection. The CryoJane Tape-Transfer System®, a commercial device that improves cryosectioning outcomes on glass slides has been reported superior for slide preparation and isolation of high quality osteocyte RNA (frozen bone) during laser dissection. Considering the reported advantages of CryoJane for laser dissection on glass slides, we asked whether the system could also work with the plastic membrane slides used by UV laser based microdissection instruments, as these are better suited for collection of larger target areas. In an attempt to optimize laser microdissection slide preparation for tissues of different RNA stability and cryosectioning difficulty, we evaluated the CryoJane system for use with both glass (laser capture microdissection) and membrane (laser cutting microdissection) slides. We have established a sample preparation protocol for glass and membrane slides including manual coating of membrane slides with CryoJane solutions, cryosectioning, slide staining and dissection procedure, lysis and RNA extraction that facilitated efficient dissection and high quality RNA retrieval from CryoJane preparations. CryoJane technology therefore has the potential to facilitate standardization of laser microdissection slide preparation from frozen tissues.

Published

2013

4. Laser Capture Microdissection for Protein and NanoString RNA Analysis

Author

Virginia Espina, Lance A. Liotta, Rosalba Salcedo, Yelena Golubeva, and Claudius Mueller

Subjects

Skin Neoplasms, Materials science, Molecular Sequence Data, Laser Capture Microdissection, Proteomics, Mass spectrometry, Article, law.invention, Mice, law, Oxazines, Microscopy, Microtome, Animals, Coloring Agents, Hematoxylin, Laser capture microdissection, Cryopreservation, Paraffin Embedding, Base Sequence, Papilloma, Staining and Labeling, Gene Expression Profiling, Proteins, RNA, Microtomy, Laser, Molecular biology, Benzoxazines, Cell culture, Ear, Inner, Biophysics, Eosine Yellowish-(YS)

Abstract

Laser capture microdissection (LCM) allows the precise procurement of enriched cell populations from a heterogeneous tissue, or live cell culture, under direct microscopic visualization. Histologically enriched cell populations can be procured by harvesting cells of interest directly, or isolating specific cells by ablating unwanted cells. The basic components of laser microdissection technology are a) visualization of cells via light microscopy, b) transfer of laser energy to a thermolabile polymer with either the formation of a polymer-cell composite (capture method) or transfer of laser energy via an ultraviolet laser to photovolatize a region of tissue (cutting method), and c) removal of cells of interest from the heterogeneous tissue section. The capture and cutting methods (instruments) for laser microdissection differ in the manner by which cells of interest are removed from the heterogeneous sample. Laser energy in the capture method is infrared (810nm), while in the cutting mode the laser is ultraviolet (355nm). Infrared lasers melt a thermolabile polymer that adheres to the cells of interest, whereas ultraviolet lasers ablate cells for either removal of unwanted cells or excision of a defined area of cells. LCM technology is applicable to an array of applications including mass spectrometry, DNA genotyping and loss-of-heterozygosity analysis, RNA transcript profiling, cDNA library generation, proteomics discovery, and signal kinase pathway profiling. This chapter describes laser capture microdissection using an ArcturusXT instrument for protein LCM sample analysis, and using a mmi CellCut Plus® instrument for RNA analysis via NanoString technology.

Published

2012