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Query: EC:2.7.7.48 (
transcriptase
)
9,479
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The basophilic leucaemia cell line RBL-2H3 exhibits a robust inwardly rectifying potassium current, IKIR, which is likely to be modulated by G proteins. We examined the physiological and molecular properties of this KIR conductance to define the nature of the underlying channel species. The macroscopic conductance revealed characteristics typical of classical K+ inward rectifiers of the IRK type. Channel gating was rapid, first order (tau approximately 1 ms at -100 mV) and steeply voltage dependent. Both activation potential and slope conductance were dependent on extracellular K+ concentration ([K+]o) and inward rectification persisted in the absence of internal Mg2+. The current was susceptible to a concentration- and voltage-dependent block by extracellular Na+, Cs+ and Ba2+. Initial IKIR whole-cell amplitudes as well as current rundown were dependent on the presence of 1 mM internal ATP. Perfusion of intracellular guanosine 5'-Q-(3-thiotriphosphate) (GTP[gamma S]) suppressed IKIR with an average half-time of decline of approximately 400 s. It was demonstrated that the dominant IRK-type 25 pS conductance channel was indeed suppressed by 100 microM preloaded GTP[gamma S]. Reverse
transcriptase
-polymerase chain reactions (RT-PCR) with RBL cell poly(A)+ RNA identified a full length K+ inward rectifier with 94% base pair homology to the recently cloned mouse
IRK1
channel. It is concluded that RBL cells express a classical voltage-dependent IRK-type K+ inward rectifier RBL-
IRK1
which is negatively controlled by G proteins.
...
PMID:Physiological and molecular characterization of an IRK-type inward rectifier K+ channel in a tumour mast cell line. 760 35
The cardiac inward rectifier current (IK1) contributes to the shape and duration of the cardiac action potential and helps to set the resting membrane potential. Although several inwardly rectifying K+ channels (IRKs) from different tissues have been cloned recently, the nature and number of K+ channels contributing to the cardiac IK1 are presently unknown. To address this issue in human heart, we have used the reverse-
transcriptase
-polymerase chain reaction (PCR) technique with human atrial total RNA as a template to identify two sequences expressed in heart that are homologous to previously cloned IRKs. One of the PCR products we obtained was virtually identical to
IRK1
(cloned from a mouse macrophage cell line); the other, which we named hIRK, exhibited < 70% identity to
IRK1
. A full-length clone encoding hIRK was isolated from a human atrial cDNA library and functionally expressed in Xenopus oocytes. This channel, like
IRK1
, exhibited strong inward rectification and was blocked by divalent cations. However, hIRK differed from
IRK1
at the single-channel level: hIRK had a single-channel conductance of 36 pS compared with 21 pS for
IRK1
. We have identified single channels of 41, 35, 21, and 9 pS in recordings from dispersed human atrial myocytes. However, none of these atrial inward rectifiers exhibited single-channel properties exactly like those of cloned hIRK expressed in oocytes. Our findings suggest that the cardiac IK1 in human atrial myocytes is composed of multiple inwardly rectifying channels distinguishable on the basis of single-channel conductance, each of which may be the product of a different gene.
...
PMID:Cloning and functional expression of an inwardly rectifying K+ channel from human atrium. 785 81
Recent studies have identified a new family of inwardly rectifying K+ channels, members of which are known by the acronyms ROMK1,
IRK1
, and GIRK1. We have isolated cDNAs encoding the human homologue of ROMK1 from an adult kidney cDNA library. The sequences of the human kidney ROMK1 cDNA clones indicated that they were derived from at least two types of mRNAs, human ROMK1A and human ROMK1B, differing in sequence at their 5' ends. The isolation of the human ROMK1 gene, localized to chromosome band 11q24 by fluorescence in situ hybridization, indicated that the different ROMK1 transcripts were generated by alternative splicing. Human ROMK1A mRNA was predicted to encode a protein of 389 amino acids, having 93% identity with the 391-residue rat ROMK1 protein, and expression studies in Xenopus oocytes indicated that it encoded a Ba(2+)-sensitive inwardly rectifying K+ channel with properties similar to those reported for cloned rat ROMK1. Human ROMK1B mRNA was predicted to encode a protein of 372 amino acids whose sequence was truncated at the amino terminus but otherwise identical to that of the human ROMK1A protein. Translation of human ROMK1B mRNA was predicted to initiate at a codon corresponding to Met-18 of human ROMK1A mRNA. Reverse
transcriptase
-polymerase chain reaction amplification of human kidney mRNA revealed human ROMK1A and -B transcripts as well as a third type of transcript, human ROMK1C mRNA, which was predicted to encode a protein identical to human ROMK1B. Human ROMK1A, -B, and -C transcripts were identified in kidney, whereas only human ROMK1A mRNA could be detected in pancreatic islets and other tissues in which human ROMK1 was expressed at low levels. Thus, tissue-specific alternative splicing of human ROMK1 mRNA may result in the expression of a family of ROMK1 proteins.
...
PMID:Alternative splicing of human inwardly rectifying K+ channel ROMK1 mRNA. 819 Jan 2
