Localization of Muscarinic Receptor mRNAs in Rat Heart and Intrinsic Cardiac Ganglia by in Situ Hybridization

Hoover, Donald B., Baisden, Ronald H., Xi-Moy, Sylvia X.

01 January 1994

Although the heart is considered a relatively pure source of m2 muscarinic receptors, the possible expression of other muscarinic receptor genes at discrete sites within the myocardium or by intrinsic cardiac ganglia had not been evaluated. Accordingly, the present study used in situ hybridization histochemistry with 35S-labeled oligonucleotide probes to address this tissue. Initial experiments demonstrated that the localization of m2 mRNA was similar to that reported for muscarinic receptors labeled with the nonselective muscarinic antagonist quinuclidinyl benzilate; however, there were two important exceptions. The conducting system contained less message than expected, whereas the intrinsic cardiac ganglia contained more. The mismatch between muscarinic receptor and m2 mRNA densities in the conducting system could not be explained by the local expression of other muscarinic receptor genes, since m1, m3, and m4 mRNAs were not detected at this or any other site within the myocardium. However, the presence of a high density of prejunctional muscarinic receptors in the conducting system would be consistent with such a mismatch. Surprisingly, the intrinsic cardiac ganglia contained more than four times as much m2 mRNA as found in the atria. This level of message may be necessary for the production of prejunctional receptors on cholinergic nerve fibers within the heart and receptors localized to the ganglion cell bodies. The ganglia also contained smaller amounts of m1 and m4 mRNAs. These observations suggest that prejunctional muscarinic receptors could have a prominent role in regulating cholinergic neurotransmission in the conducting system and that multiple muscarinic receptors are present in the intrinsic cardiac ganglia.

cardiac ganglia

heart

in situ hybridization

mRNA

muscarinic receptor

Biomedical Sciences

3D-FISH analysis of the spatial genome organization in skin cells in situ

Mardaryev, Andrei N., Fessing, Michael Y.

25 May 2021

No / Spatial genome organization in the cell nucleus plays a crucial role in the control of genome functions. Our knowledge about spatial genome organization is relying on the advances in gene imaging technologies and the biochemical approaches based on the spatial dependent ligation of the genomic regions. Fluorescent in situ hybridization using specific fluorescent DNA and RNA probes in cells and tissues with the spatially preserved nuclear and genome architecture (3D-FISH) provides a powerful tool for the further advancement of our knowledge about genome structure and functions. Here we describe the 3D-FISH protocols allowing for such an analysis in mammalian tissue in situ including in the skin. These protocols include DNA probe amplification and labeling; tissue fixation; preservation and preparation for hybridization; hybridization of the DNA probes with genomic DNA in the tissue; and post-hybridization tissue sample processing.

Epigenetics

Spatial genome organization

Fluorescent in situ hybridization

3D FISH analysis

Bacterial communities in a Northeast Ohio stream: effects of substrate size, environmental features and temporal changes

Santmire, Judith Ann

13 April 2005

No description available.

bacterial communities

substrate

lotic

fluorescent in situ hybridization

sediment

Unusual eye design: The compound-lens eyes of Strepsiptera and the scanning eyes of Sunburst Diving Beetle larvae

Maksimovic, Srdjan

January 2010

No description available.

Neurology

insects

eyes

optomotor response

stemmata

in situ hybridization

opsins

Application of Fluorescence in situ Hybridization for Visualization and Quantification of Human Gastrointestinal Microbiota

Gordon, Alexander M.

31 August 2015

No description available.

Microbiology

Biomedical Research

Gastrointestinal Microbiota

Fluorescence in situ Hybridization

FISH

The study of glucose-6-phosphate dehydrogenase (G6PD) gene regulation in HepG2 cells by glucose induction and the study of G6PD mRNA localization by fluorescent in situ hybridization (FISH)

Griffith, Brian Nelson.

January 2002

Thesis (M.S.)--West Virginia University, 2002. / Title from document title page. Document formatted into pages; contains viii, 100 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 80-96).

Real time PCR and fluorescent in situ hybridization in the detection of the physical tsate of human papillomavirus 16 and 18 in paraffin embedded cervical tissue

Davis, Aisha

07 1900

Indiana University Purdue University Indianapolis / Human papillomaviruses (HPV) are the etiologic agents of most cervical dysplasia and all cervical carcinoma. Integration of high risk HPV into the human genome is thought to be a critical event in the progression from cervical dysplasia to invasive cervical carcinoma. The ability to use molecular assays in the detection and evaluation of HPV integration is essential in informing clinical models for early intervention and therapies. We therefore sought to determine the feasibility of real time-PCR (RT-PCR) as a molecular tool in detecting the physical state, episomal versus integration of HPV 16 and 18 DNA in cervical cancers. Tyramide amplified fluorescent DNA in situ hybridization (FISH) was used to look for evidence of HPV 16/18 integration using formalin-fixed, paraffin-embedded sections of cervical carcinomas. RT-PCR used the ratio of the E2 and E6 genes as a surrogate for determining the physical state of HPV 16 and 18 in 35 infected tissues. Results of RT-PCR showed that 16 cervical specimens (45.7%) contained episomal HPV, 17 cervical samples (48.6%) harbored the integrated form of HPV DNA, and 2 samples (5.7 %) contained both integrated and episomal forms of HPV. Results of the two assays were compared in 25 cervical carcinomas. For 13 of the 25 cervical samples there was an agreement in determining the physical state of HPV. RT-PCR, using the E2/E6 ratio as an assay for HPV integration appears to be promising and may prove to be an essential clinical method in the future.

Real Time PCR

Fluorescent in situ hybridization

Human papillomavirus

HPV

Cervical tissue

Cervical cancer

Papillomaviruses

Cervix uteri -- Cancer

In situ hybridization

DNA damage

DEVELOPMENT AND APPLICATION OF NOVEL QUANTITATIVE AND QUALITATIVE MOLECULAR TECHNIQUES FOR DETECTION OF INFECTIOUS MYONECROSIS VIRUS (IMNV) IN PACIFIC WHITE SHRIMP LITOPENAEUS VANNAMEI

Andrade, Thales Passos de

January 2009

Infectious myonecrosis, caused by infectious myonecrosis virus (IMNV), is an important disease of shrimp that has adversely affected the production of cultured Litopenaeus vannamei. The studies reported here were centered on development and/or validation of alternative diagnostic methods for detection of IMNV. Hence, two manuscripts were published in the Journal of Aquaculture and one manuscript was published in the Journal of Fish Diseases. Chapter 2 describes the development of a real-time reverse transcription polymerase chain reaction (real-time RT-PCR) method using TaqMan probe. The results showed that this real-time RT-PCR assay can detect as little as 10 IMNV copies/μl RNA, while the nested RT-PCR can detect 1000 copies/μl RNA. These findings suggest that the TaqMan real-time RT-PCR is “the gold standard” for screening shrimp to protect aquaculture production systems from losses caused by IMNV, because it provides quantification, higher sensitivity and specificity, and because it is less time consuming and less prone to contamination compared to conventional gel-based RT-PCR. In Chapter 3 I evaluated if prolonged storage of infectious myonecrosis virus (IMNV) infected shrimp in Davidson’s AFA fixative can degrade its double-stranded RNA genome resulting in false negative ISH reactions. Shrimp were collected at Day 12 post-injection and fixed in Davidson’s AFA for five different preservation times (1, 2, 4, 7 and 10 days). Hence, in the present report it was found that the length of time (up to 10 days) in Davidson’s AFA did not have a deleterious effect on the ISH reaction for IMNV. The Chapter 4 describes the development of a reverse transcription loop-mediated isothermal amplification and nucleic acid lateral flow (RT-LAMP-NALF) for detection of IMNV. The RT-LAMP-NALF method combines simplified nucleic acid extraction, a reverse-transcription loop-mediated isothermal amplification platform, and one-step visual colorimetric confirmation of the IMNV amplified sequences using a generic NALF qualitative detection test strip. The RT-LAMP-NALF was found to be 100 and 10 times more sensitive than one-step RT-PCR and RT-LAMP (two primer pairs), respectively. These results clearly demonstrate that the RT-LAMP-NALF method is specific, sensitive, can shorten the time for analysis, and has potential application for IMNV diagnosis in resource-poor diagnostic settings.

IMNV

in situ hybridization

INFECTIOUS MYONECROSIS VIRUS

Litopenaeus vannamei

Real-time RT-PCR

RT-LAMP-NALF

Dense populations of the microsporidian Enterocytozoon hepatopenaei (EHP) in feces of Penaeus vannamei exhibiting white feces syndrome and pathways of their transmission to healthy shrimp.

Tang, Kathy F J, Han, Jee Eun, Aranguren, Luis Fernando, White-Noble, Brenda, Schmidt, Margeaux M, Piamsomboon, Patharapol, Risdiana, Eris, Hanggono, Bambang

10 1900

White feces syndrome (WFS) is an emerging problem for penaeid shrimp farming industries in SE Asia countries, Thailand, Malaysia, Vietnam, Indonesia, China, and in India. This occurrence of this syndrome is usually first evidenced by the appearance of white fecal strings floating on surface of the shrimp ponds. The gross signs of affected shrimp include the appearance of a whitish hindgut and loose carapace, and it is associated with reduced feeding and growth retardation. To investigate the nature of the white feces syndrome, samples of white feces and shrimp hepatopancreas tissue were collected from Penaeus vannamei in affected farms in Indonesia, and these were examined histologically. Within the white feces, we found densely packed spores of the microsporidian Enterocytozoon hepatopenaei (abbreviated as EHP) and relatively fewer numbers of rod-shaped bacteria. From WFS ponds, hepatopancreas samples form 30 individual shrimp were analyzed by histology and in situ hybridization. The results showed that all of the shrimp examined were infected with EHP accompanied by septic hepatopancreatic necrosis (SHPN). Midgut epithelial cells were also infected and this increased the number of tissue types being affected by EHP. By PCR, EHP was detected in all the samples analyzed from WFS-affected ponds, but not in those sampled from healthy shrimp ponds. To determine the modes of transmission for this parasite, we performed feeding and cohabitation bioassays, the results showed that EHP can be transmitted through per os feeding of EHP-infected hepatopancreas tissue to healthy shrimp and through cohabitation ofinfected and healthy shrimp. In addition, we found the use of Fumagillin-B, an antimicrobial agent, was ineffective in either reducing or eliminating EHP in infected shrimp.

Shrimp disease

Enterocytozoon hepatopenaei

EHP

White feces syndrome

In situ hybridization

PCR

Nouvelle approche de décryptage de la diversité bactérienne environnementale par capture magnétique de populations spécifiques de bactéries au sein de microbiotes complexes / Development of magnetic in situ hybridization technics for labelling and selective capture of bacteria for the study of environmental bacterial biodiversity.

Royet, David

16 March 2017

Les bactéries, organismes les plus abondants de notre planète, ont un rôle fondamental dans le fonctionnement des écosystèmes. En dépit de leur importance, la caractérisation des communautés bactériennes (microbiotes) demeure encore aujourd’hui très incomplète. Ceci a pour origine l’impossibilité de complètement décrypter taxonomiquement et fonctionnellement les microbiotes de ces écosystèmes et donc à appréhender la diversité bactérienne dans son ensemble que ce soit par des approches culturales (avec seulement 1% de bactéries cultivables) ou par des approches metagénomiques limitées par les biais d’extraction, de séquençage et d’analyse. Les travaux entrepris dans le cadre de cette thèse visent à développer une nouvelle voie exploratoire passant par le fractionnement des microbiotes afin d’en étudier séparément les génomes des différentes populations ou groupes de populations, leur somme devant permettre de reconstituer un metagénome complet. Cet objectif requiert le développement d’un outil pour la sélection spécifique de bactéries (sur des critères taxonomiques ou fonctionnels) et leur isolement du reste des microorganismes non ciblés. Les travaux de thèse ont porté sur le développement d’une approche de marquage magnétique des bactéries basée sur l’hybridation moléculaire (hybridation in situ) complétée par celui d’un outil de tri microfluidique. Deux méthodes ont été développées, MISH et HCR, ciblant le gène de l’ARNr 23S, chacune reposant sur la formation, lors du processus d’hybridation, d’une structure secondaire en arborescence (MISH) ou ordonnée (HCR) permettant le greffage de nanoparticules magnétiques. Les résultats obtenus illustrent le potentiel des deux approches d’abord pour le marquage spécifique de bactéries cibles (E.coli et Pseudomonas putida) en conditions de culture au laboratoire puis dans un second temps dans des échantillons de sol. Le tri microfluidique a également été optimisé par le développement d’un nouveau dispositif de tri magnétique permettant la séparation des cellules marquées sous flux continu faisant appel à l’injection d’un polymère composite magnétique pour intégrer au fond du microcanal une série de bandes parallèles magnétiques. La fonctionnalité du dispositif a été démontrée, sa simplicité de fabrication en faisant un outil de choix pour une application en routine dans les laboratoires d’écologie microbienne. En dépit de résultats prometteurs toute cette nouvelle approche d’étude de la diversité bactérienne environnementale nécessite encore de nombreuses étapes d’optimisation. / Bacteria, the most abundant organisms on our planet, have a fundamental role in ecosystem functioning. Despite their importance, the characterization of bacterial communities is today still incomplete. This is due to the impossibility of completely decomposing taxonomically and functionally the microbial communities of these ecosystems and as a consequence to apprehend the whole bacterial diversity, either by cultural approaches (with only 1% of culturable bacteria) or by metagenomic, a limited approaches cause by biases in extraction, sequencing and analysis. The work undertaken in this thesis aims to develop a new exploratory pathway through the fractionation of microbiota in order to study separately genomes of different populations or groups of populations. Their sum should enable reconstitution of complete metagenome. This objective requires the development of a tool for the specific selection of bacteria (on taxonomic or functional criteria) and their isolation from the rest of the non-target microorganisms. The thesis work focused on the development of a magnetic labeling approach for bacteria based on molecular hybridization (in situ hybridization) complete by development of a microfluidic cell-sorting tool. Two methods have been developed, MISH and HCR, targeting the 23S rRNA gene, each based on the formation, during the hybridization process, of a secondary random structure (MISH) or organized structure (HCR) enabling binding to magnetic nanoparticles. Results obtained illustrate the potential of the two approaches initially for the specific labeling of target bacteria (E.coli and Pseudomonas putida) under laboratory conditions and then in soil samples. The microfluidic sorting was also optimized by the development of a novel magnetic cell-sorting device allowing the separation of the labeled cells under continuous flow using the injection of a magnetic composite polymer to integrate a series of magnetic parallel strips at the bottom of the microchannel. The proper functioning of the sorting device has been demonstrated, its simple production making it a tool of choice for a routine application in laboratories of microbial ecology. Despite promising results all this new approach for studying environmental bacterial diversity is still requiring many optimization steps.

Hybridation in situ

Écologie microbienne

Tri cellulaire

Microsystèmes

Magnétisme

In situ hybridization

Microbial ecology

Cell-sorting

Microsystems

Magnetism