Optimization of phosphorus localization by EFTEM of nucleic acid containing structures

Abstract Energy Filtered Transmission Electron Microscopy (EFTEM) has been used to study nucleic acids localization in unstained thin sections of virus-infected cells. For this purpose, phosphorus maps (P-maps) have been obtained by applying the N-windows Egerton model for background subtraction from data acquired by a non-dedicated TEM Jeol 1200EXII equipped with a post-column PEELS Gatan 666–9000 and a Gatan Image Filter (GIF-100). To prevent possible errors in the evaluation of elemental maps and thus incorrect nucleic acid localization, we have studied different regions of swine testis (ST) cells with similar local density containing either high concentration of nucleic acids (condensed chromatin and ribosomes) or a very low concentration (mitochondria). Special care was taken to optimize the sample preparation conditions to avoid as much as possible the traditional artifacts derived from this source. Selection of the best set of pre-edge images for background fitting was also considered in order to produce “true P-maps”. A new software for interactive processing of images series has been applied to estimate this set. Multivariate Statistical Analysis was used as a filtering tool to separate the “useful information” present in the inelastic image series (characteristic signal) from the “non-useful information” (noise and acquisition artifacts). The reconstitution of the original image series preserving mainly the useful information allowed the computation of P-maps with improved signal-to-noise ratio (SNR). This methodology has been applied to study the RNA content of maturation intermediate coronavirus particles found inside infected cells.

[1]  G. Harauz,et al.  Three-dimensional architecture of Thermomyces lanuginosus small subunit ribosomal RNA , 1997 .

[2]  N Bonnet,et al.  Analysis of image sequences in fluorescence videomicroscopy of stationary objects. , 1998, Cytometry.

[3]  G Harauz,et al.  Nucleosome reconstruction via phosphorus mapping. , 1984, Science.

[4]  J. W. Andrew,et al.  High-resolution microanalysis of biological specimens by electron energy loss spectroscopy and by electron spectroscopic imaging. , 1980, Journal of ultrastructure research.

[5]  O. Krivanek,et al.  Design and first applications of a post-column imaging filter , 1992 .

[6]  C Jeanguillaume,et al.  Electron energy loss spectrometry mapping , 1994 .

[7]  R. Leapman Scanning Transmission Electron Microscope (STEM) Elemental Mapping by Electron Energy‐Loss Spectroscopy , 1986, Annals of the New York Academy of Sciences.

[8]  N. Bonnet,et al.  Improvements in biological X-ray microanalysis: cryoembedding for specimen preparation and multivariate statistical analysis for data interpretation. , 1994, Scanning microscopy. Supplement.

[9]  R. Egerton Inelastic scattering of 80 keV electrons in amorphous carbon , 1975 .

[10]  D. Andrews,et al.  Elemental imaging by electron energy loss microscopy , 1988 .

[11]  F. Ottensmeyer EIemental Mapping by Energy Filtration: Advantages, Limitations, and Compromises a , 1986, Annals of the New York Academy of Sciences.

[12]  G. Vázquez-Nin Phosphorus distribution in perichromatin granules and surrounding nucleoplasm as visualized by electron spectroscopic imaging , 1996 .

[13]  C Mory,et al.  EELS elemental mapping with unconventional methods. II. Applications to biological specimens. , 1990, Ultramicroscopy.

[14]  G. Harauz,et al.  The in situ architecture of Escherichia coli ribosomal RNA derived by electron spectroscopic imaging and three‐dimensional reconstruction , 1997, Journal of microscopy.

[15]  L. Enjuanes,et al.  Membrane protein molecules of transmissible gastroenteritis coronavirus also expose the carboxy-terminal region on the external surface of the virion , 1995, Journal of virology.

[16]  C. Quintana X-ray microanalysis of cell nuclei. , 1991, Journal of electron microscopy technique.

[17]  An imaging filter for biological applications. , 1995, Ultramicroscopy.

[18]  G. Harauz,et al.  Electron spectroscopic imaging of encapsidated DNA in vaccinia virus. , 1995, Canadian journal of microbiology.

[19]  L. Reimer,et al.  Contrast in the electron spectroscopic imaging mode of a TEM , 1990 .

[20]  Noël Bonnet,et al.  Processing of images and image series: A tutorial review for chemical microanalysis , 1995 .

[21]  N. Bonnet,et al.  Multivariate statistical analysis applied to X-ray spectra and X-ray mapping of liver cell nuclei. , 1994, Scanning microscopy.

[22]  N Bonnet,et al.  EELS elemental mapping with unconventional methods. I. Theoretical basis: image analysis with multivariate statistics and entropy concepts. , 1990, Ultramicroscopy.

[23]  D. Hockley,et al.  A morphological and immunolabelling study of freeze-substituted human and simian immunodeficiency viruses. , 1994, Micron.

[24]  F. P. Ottensmeyer,et al.  Spatial resolution and detection sensitivity in microanalysis by electron energy loss selected imaging , 1981, Journal of microscopy.

[25]  E. J. Breen,et al.  Regression methods for automated colour image classification and thresholding , 1994 .

[26]  D. Bazett-Jones,et al.  Phosphorus distribution in the nucleosome. , 1981, Science.

[27]  C Jeanguillaume,et al.  About the use of electron energy-loss spectroscopy for chemical mapping of thin foils with high spatial resolution. , 1978, Ultramicroscopy.

[28]  J Frank,et al.  Reconstitution of molecule images analysed by correspondence analysis: A tool for structural interpretation , 1986, Journal of Microscopy.

[29]  W. Grogger,et al.  Imaging of nanometer-sized precipitates in solids by electron spectroscopic imaging , 1995 .

[30]  F. Ottensmeyer,et al.  Experimental ionization cross‐sections of phosphorus and calcium by electron spectroscopic imaging , 1990, Journal of microscopy.

[31]  J. L. Taft,et al.  Phosphorus Distribution in the , 1976 .

[32]  D. Bazett-Jones,et al.  Osmium ammine-B and electron spectroscopic imaging of ribonucleoproteins: correlation of stain and phosphorus. , 1996, Biology of the Cell.

[33]  M. Ozel,et al.  Electron spectroscopic imaging (ESI) of viruses using thin-section and immunolabelling preparations. , 1990, Ultramicroscopy.

[34]  B. W. Frankland,et al.  Spectral processing for parallel recording of elemental maps. , 1988, Scanning microscopy. Supplement.

[35]  A. Korn,et al.  Specific visualization of ribosomal RNA in the intact ribosome by electron spectroscopic imaging. , 1983, European journal of cell biology.

[36]  C. Quintana,et al.  Evaluation of the analytical and imaging performances of a non-dedicated TEM equipped with a parallel electron energy loss spectrometer (PEELS) and image filter (IF) , 1997 .

[37]  C. Quintana Cryofixation, cryosubstitution, cryoembedding for ultrastructural, immunocytochemical and microanalytical studies. , 1994, Micron.

[38]  S D Davilla,et al.  Real‐time quantitative elemental analysis and mapping: microchemical imaging in cell physiology , 1992, Journal of microscopy.

[39]  R. Leapman,et al.  Comparison of detection limits for EELS and EDXS , 1991 .

[40]  S. Fakan,et al.  Image‐EELS for in situ estimation of the phosphorus content of RNP granules , 1996 .

[41]  N Bonnet,et al.  Developments in processing image sequences for elemental mapping. , 1988, Scanning microscopy. Supplement.

[42]  K. Kimoto,et al.  Spatial resolution in EFTEM elemental maps , 1995 .

[43]  Noël Bonnet,et al.  New applications of multivariate statistical analysis in spectroscopy and microscopy , 1992 .