Anne Skvorak scite author profile

Anne Skvorak

2Publications

40Citation Statements Received

79Citation Statements Given

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Louis-Jeantet Foundation

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Monoclonal antibodies to yeast poly(A) polymerase (PAP) provide evidence for association of PAP with cleavage factor I

Kessler

Zhelkovsky²,

Skvorak³

et al. 1995

Biochemistry

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Purified yeast poly(A) polymerase (PAP) was used to produce monoclonal antibodies which recognize the enzyme in immunoblots. Epitope mapping using truncated forms of PAP and cyanogen bromide cleavage products revealed two classes of antibodies. One class (N-term) recognizes an epitope in the first 100 amino acids, and a second class (C-term) is specific for a determinant located in the last 20 amino acids of PAP. These C-terminal 20 amino acids can be removed without affecting the nonspecific poly(A) addition activity of the purified enzyme. Neither antibody inhibits the nonspecific poly(A) polymerase activity or the sequence-specific activity observed in processing extracts. The antibodies show species specificity and cannot recognize mammalian, Xenopus, or vaccinia PAP. The C-term antibodies can deplete PAP from yeast whole cell extracts, resulting in loss of poly(A) addition activity. This immunodepletion also causes a reduction in the cleavage activity which can be restored by addition of yeast cleavage factor I [CF I; Chen, J., & Moore, C. (1992) Mol. Cell Biol. 12, 3470-3481], a factor needed for both the cleavage and poly(A) addition reactions. This demonstrates that a complex of PAP and CF I exists in extracts in the absence of ATP or exogenous RNA substrate. The monoclonal antibodies against yeast PAP will be a useful tool for further study of factors required for yeast mRNA 3' end processing.

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Oxidation of rat insulin II, but not I, leads to anomalous elution profiles upon HPLC analysis of insulin‐related peptides

et al. 1988

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Rat insulin II, unlike rat insulin I and other non-rodent insulins, contains a unique methionine residue at position B29. Reversed-phase HPLC allows for separation of the two rat insulins, with insulin I typically eluting faster than insulin II. An anomalous peak of insulin immunoreactive material was found eluting even faster than insulin I following acid extraction of rat insulin-producing cells. This early peak co-eluted with insulin II suggesting that during cell extraction and subsequent purification steps, rat insulin II is subject to selective oxidation at Met s29. Such oxidation of rat proinsulin II affords improved separation from rat proinsulin I compared to the native form.

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Anne Skvorak

Monoclonal antibodies to yeast poly(A) polymerase (PAP) provide evidence for association of PAP with cleavage factor I

Oxidation of rat insulin II, but not I, leads to anomalous elution profiles upon HPLC analysis of insulin‐related peptides

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