Search results for "Mono"
showing 10 items of 6843 documents
Immunoelectron Microscopy of Hemocyanin from the Keyhole Limpet (Megathura crenulata): A Parallel Subunit Model
1993
Abstract Immunoelectron microscopy has been performed using negatively stained immune complexes of keyhole limpet hemocyanin (KLH) subunit 2 di- and multidecamers with domain-specific monoclonal antibodies. One antibody (KLH2 a macr 1) links the hemocyanin molecules in a side-to-side pattern, whereas the other antibody (KLH2 fg macr 1) links the molecules end-to-end. From existing knowledge of the domain sequence of KLH subunit 2, these data provide support for a parallel arrangement of subunits within each decamer. Ten N-terminal a macr: domains are then present at the noncollar region of each decamer with 10 C-terminal g macr domains at the collar region. The immunonegative staining data …
Targeting Angiogenesis by Therapeutic Antibodies
2014
SISTEMI D’INTERESSE FARMACEUTICO INTERAZIONE CON MODELLI DI BIOMEMBRANA MEDIANTE METODI CHIMICO-FISICI: TECNICHE CALORIMETRICHE E MONOLAYERS
2012
Cloning of an alkane hydroxylase system in a long chain n-alkane- degrader Gordonia sp.
2008
Five Gram-positive GC rich n-alkane degraders were isolated from a long-term accidentally contaminated beach in Sicily and identified as one Nocardia, two Rhodococcus and two Gordonia strains (Quatrini et al., 2008 J. Appl. Microbiol. 104:251-9). All the isolates were able to grow on long and very long chain n-alkanes up to C36. Diverging alkane-hydroxylase encoding genes (alkB) were detected by PCR using degenerated primers in all the strains. Multiple sequences were obtained from the Nocardia strain while only one alkB gene was detected in Rhodococcus and Gordonia. The aim of this work is to genetically characterize the alk cluster in one of the two Gordonia strains called SoCg. Pulsed Fi…
CCDC 1835272: Experimental Crystal Structure Determination
2021
Related Article: Mamadou Ndiaye, Mouhamadou Birame Diop, Abdoulaye Samb, Libasse Diop, Allen G. Oliver, Laurent Plasseraud|2020|Zeitschrift fuer Naturforschung, Teil B. Anorganische Chemie, Organische Chemie|75|815 |doi:10.1515/znb-2020-0097
CCDC 1491308: Experimental Crystal Structure Determination
2016
Related Article: Verónica Jornet-Mollá, Yan Duan, Carlos Giménez-Saiz, João C. Waerenborgh, Francisco M. Romero|2016|Dalton Trans.|45|17918|doi:10.1039/C6DT02934E
CCDC 725083: Experimental Crystal Structure Determination
2010
Related Article: G.Agusti, C.Bartual, V.Martinez, F.J.Munoz-Lara, A.B.Gaspar, M.C.Munoz, J.A.Real|2009|New J.Chem.|33|1262|doi:10.1039/b905674b
CCDC 725084: Experimental Crystal Structure Determination
2010
Related Article: G.Agusti, C.Bartual, V.Martinez, F.J.Munoz-Lara, A.B.Gaspar, M.C.Munoz, J.A.Real|2009|New J.Chem.|33|1262|doi:10.1039/b905674b
CCDC 725085: Experimental Crystal Structure Determination
2010
Related Article: G.Agusti, C.Bartual, V.Martinez, F.J.Munoz-Lara, A.B.Gaspar, M.C.Munoz, J.A.Real|2009|New J.Chem.|33|1262|doi:10.1039/b905674b
CCDC 158446: Experimental Crystal Structure Determination
2005
Related Article: R.Boca, F.Renz, M.Boca, H.Fuess, W.Haase, G.Kickelbick, W.Linert, M.Vrbova-Schikora|2005|Inorg.Chem.Commun.|8|227|doi:10.1016/j.inoche.2004.12.014