Lee Ann Johnston scite author profile

We determined the fidelity of avian myeloblastosis virus and Moloney murine leukemia virus reverse transcriptases (RTs) during DNA synthesis in vitro using the M13mp2 lacZa gene as a mutational target Retroviral reverse transcriptases (RTs) (EC 2.7.7.7) are DNA polymerases that transcribe retroviral genomic RNA into double-stranded DNA. RT was first identified in virions of murine leukemia virus (MuLV) by Baltimore (1) and Rous sarcoma virus by Temin and Mizutani (54). These enzymes perform multiple enzymatic functions, including the copying of RNA into DNA, the hydrolysis of the RNA from an RNA-DNA hybrid (RNase H), and the copying of singlestranded DNA into double-stranded DNA; thus, RT plays a central role in the life cycle of retroviruses (55,56).The physical structure of purified RT from avian and murine retroviruses has been studied extensively (for a review, see reference 58). Avian retrovirus RT is a heterodimeric molecule containing two related subunits, one with a molecular size of -63 kilodaltons (the a subunit) and the other -95 kilodaltons (the ( subunit) (18). These two proteins, along with a pp32Pol phosphoprotein endonuclease, are derived by differential processing of a pol polyprotein precursor (45). The endonuclease specifically nicks DNA at the junction of adjacent retroviral long terminal repeat sequences (14). The a subunit of avian RT appears to carry both polymerase and RNase H activities.The murine retroviral RT differs from the avian form in that it is a single 84-kilodalton polypeptide (57). Finestructure mutational analysis of the murine enzyme indicated that both the polymerase and the RNase H activities are contained in this polypeptide, with the polymerase activity mapping to the N terminus and the RNase H activity at the C terminus (52). Thus, the murine RT appears to be analogous to the a subunit of the avian RT.

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Molecular cloning and subcellular distribution of the novel PDE4B4 cAMP-specific phosphodiesterase isoform

Shepherd

McSorley

Olsen

et al. 2003

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We have isolated cDNAs encoding PDE4B4, a new cAMP-specific phosphodiesterase (PDE4) isoform with novel properties. The amino acid sequence of PDE4B4 demonstrates that it is encoded by the PDE4B gene, but that it differs from the previously isolated PDE4B1, PDE4B2 and PDE4B3 isoforms by the presence of a novel N-terminal region of 17 amino acids. PDE4B4 contains both of the upstream conserved region 1 (UCR1) and UCR2 regulatory units that are characteristic of 'long' PDE4 isoforms. RNase protection demonstrated that PDE4B4 mRNA is expressed preferentially in liver, skeletal muscle and various regions of the brain, which differs from the pattern of tissue distribution of the other known PDE4B long forms, PDE4B1 and PDE4B3. Expression of PDE4B4 cDNA in COS7 cells produced a protein of 85 kDa under denaturing conditions. Subcellular fractionation of recombinant, COS7-cell expressed PDE4B4 showed that the protein was localized within the cytosol, which was confirmed by confocal microscopic analysis of living COS7 cells transfected with a green fluorescent protein-PDE4B4 chimaera. PDE4B4 exhibited a K(m) for cAMP of 5.4 microM and a V(max), relative to that of the long PDE4B1 isoform, of 2.1. PDE4B4 was inhibited by the prototypical PDE4 inhibitor rolipram [4-[3-(cyclopentoxyl)-4-methoxyphenyl]-2-pyrrolidinone] with an IC(50) of 83 nM. Treatment of COS7 cells with forskolin, to elevate cAMP levels, produced activation of PDE4B4, which was associated with the phosphorylation of PDE4B4 on Ser-56 within UCR1. The unique tissue distribution and intracellular targeting of PDE4B4 suggests that this isoform may have a distinct functional role in regulating cAMP levels in specific cell types.

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Identification and Characterization of PDE4A11, a Novel, Widely Expressed Long Isoform Encoded by the Human PDE4A cAMP Phosphodiesterase Gene

Wallace

Johnston²,

Huston³

et al. 2005

Mol Pharmacol

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PDE4A11 is a novel cAMP-specific phosphodiesterase that is conserved in humans, mouse, rat, pig, and bat. Exon-1 4A11 encodes its unique, 81 amino acid N-terminal region. Reverse-transcriptase polymerase chain reaction performed across the splice junction, plus identification of expressed sequence tags, identifies PDE4A11 as a long isoform possessing UCR1 and UCR2 regulatory domains. Transcript analysis shows that PDE4A11 is widely expressed compared with PDE4A10 and PDE4A4B long isoforms. Truncation analysis identifies a putative promoter in a 250-base pair region located immediately upstream of the start site in Exon-1 4A11. Recombinant PDE4A11, expressed in COS-7 cells, is a 126-kDa protein localized predominantly around the nucleus and in membrane ruffles. PDE4A11 exhibits a K m for cAMP hydrolysis of 4 M, with relative V max similar to that of PDE4A10 and PDE4A4B. PDE4A11 is dose-dependently inhibited by rolipram, 4-[(3-butoxy-4-methoxyphenyl)-methyl]-2-imidazolidinone (Ro 20-1724), cilomilast, roflumilast, and denbufylline, with IC 50 values of 0.7, 0.9, 0.03, 0.004, and 0.3 M, respectively. Soluble and particulate PDE4A11 exhibit distinct rates of thermal inactivation (55°C; T (0.5) ϭ 2.5 and 4.4 min, respectively). Elevating cAMP levels in COS-7 cells activates PDE4A11 concomitant with its phosphorylation at Ser119 by protein kinase A (PKA). PDE4A11 differs from PDE4A4 in sensitivity to cleavage by caspase-3, interaction with LYN SH3 domain, redistribution upon long-term rolipram challenge, and sensitivity to certain PDE4 inhibitors. PDE4A11, PDE4A10, and PDE4A4 all can interact with ␤arrestin.

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Fidelity of Two Retroviral Reverse Transcriptases during DNA-Dependent DNA Synthesis In Vitro

Roberts

Preston

Johnston

et al. 1989

Molecular and Cellular Biology

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We determined the fidelity of avian myeloblastosis virus and Moloney murine leukemia virus reverse transcriptases (RTs) during DNA synthesis in vitro using the M13mp2 lacZ alpha gene as a mutational target. Both RTs commit an error approximately once for every 30,000 nucleotides polymerized. DNA sequence analysis of mutants generated in a forward mutation assay capable of detecting many types of errors demonstrated that avian myeloblastosis virus RT produced a variety of different mutations. The majority (58%) were single-base substitutions; all of which resulted from the misincorporation of either dAMP or dGMP. Minus-one frameshifts were also common, composing about 30% of the mutations. In addition to single-base events, eight mutants contained sequence changes involving from 2 to 59 bases. The frequency of these mutants suggests that, at least during DNA synthesis in vitro, RTs also commit errors by mechanisms other than classical base miscoding and misalignment. We examined the ability of RTs to synthesize DNA from a mismatched primer terminus at a sequence where the mismatched base was complementary to the next base in the template. Unlike cellular DNA polymerases which polymerize from the mismatched template-primer, RTs preferred to polymerize from a rearranged template-primer containing a matched terminal base pair and an unpaired base in the template strand. The unusual preference for this substrate suggests that the interactions between RTs and the template-primer are different from those of cellular DNA polymerases. The overall error rate of RT in vitro is sufficient to account for the estimated mutation rate of these viruses.

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Expression, intracellular distribution and basis for lack of catalytic activity of the PDE4A7 isoform encoded by the human PDE4A cAMP-specific phosphodiesterase gene

Johnston

Erdoğan

Cheung

et al. 2004

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PDE4A7 is an isoform encoded by the human PDE4A cAMP-specific phosphodiesterase gene that fails to hydrolyse cAMP and whose transcripts are widely expressed. Removal of either the N- or C-terminal unique portions of PDE4A7 did not reconstitute catalytic activity, showing that they did not exert a chronic inhibitory effect. A chimera (Hyb2), formed by swapping the unique N-terminal portion of PDE4A7 with that of the active PDE4A4C form, was not catalytically active. However, one formed (Hyb1) by swapping the unique C-terminal portion of PDE4A7 with that common to all active PDE4 isoforms was catalytically active. Compared with the active PDE4A4B isoform, Hyb1 exhibited a similar K(m) value for cAMP and IC50 value for rolipram inhibition, but was less sensitive to inhibition by Ro-20-1724 and denbufylline, and considerably more sensitive to thermal denaturation. The unique C-terminal region of PDE4A7 was unable to support an active catalytic unit, whereas its unique N-terminal region can. The N-terminal portion of the PDE4 catalytic unit is essential for catalytic activity and can be supplied by either highly conserved sequence found in active PDE4 isoforms from all four PDE4 subfamilies or the unique N-terminal portion of PDE4A7. A discrete portion of the conserved C-terminal region in active PDE4A isoforms underpins their aberrant migration on SDS/PAGE. Unlike active PDE4A isoforms, PDE4A7 is exclusively localized to the P1 particulate fraction in cells. A region located within the C-terminal portion of active PDE4 isoforms prevents such exclusive targeting. Three functional regions in PDE4A isoforms are identified, which influence catalytic activity, subcellular targeting and conformational status.

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Lee Ann Johnston

Fidelity of two retroviral reverse transcriptases during DNA-dependent DNA synthesis in vitro.

Molecular cloning and subcellular distribution of the novel PDE4B4 cAMP-specific phosphodiesterase isoform

Identification and Characterization of PDE4A11, a Novel, Widely Expressed Long Isoform Encoded by the Human PDE4A cAMP Phosphodiesterase Gene

Fidelity of Two Retroviral Reverse Transcriptases during DNA-Dependent DNA Synthesis In Vitro

Expression, intracellular distribution and basis for lack of catalytic activity of the PDE4A7 isoform encoded by the human PDE4A cAMP-specific phosphodiesterase gene

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