George M. Church scite author profile

George M. Church

3Publications

18Citation Statements Received

19Citation Statements Given

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168

Affiliations

Harvard University, Albany Medical Center Hospital

Publications

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Stimulation of Carbonic Anhydrase Activity and Phosphorylation in Primary Astroglial Cultures by Norepinephrine

Church

Kimelberg

Sapirstein

1980

Journal of Neurochemistry

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The carbonic anhydrase activity of 3‐week‐old primary astroglial cultures started from the dissociated cerebral hemispheres of neonatal rats was increased up to twofold after treatment of the cultures with 0.1 mM‐norepinephrine or histamine. Stimulation due to addition of norepinephrine was inhibited by propranolol. The carbonic anhydrase activity of primary cultures derived from the cerebellum plus brain stem regions was about fourfold greater than the activity of primary cultures started from cerebral hemispheres, but in contrast was not stimulated by norepinephrine. Treatment of the cerebral cultures with norepinephrine in the presence of 32P resulted in a two‐ to threefold increased incorporation of 32P into carbonic anhydrase purified from the same cultures, and this increased incorporation was inhibited by propranolol. It is suggested that one of the consequences of the stimulation of 3′,5′‐cyclic AMP levels in brain by norepinephrine is activation of astroglial carbonic anhydrase activity due to 3′5′‐cyclic AMP‐stimulated phosphorylation of the enzyme.

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Swelling and ion uptake in cat cerebrocortical slices:

et al. 1983

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Cat cerebrocortical slices incubating in medium containing normal K+ concentrations were exposed to a number of different transmitters. Norepinephrine, histamine and adenosine or 2-chloroadenosine caused increased swelling of the slices associated with an increased Na+ and Cl- content. These effects were seen only when both Cl- and HCO3- were present in the medium, and were inhibited by a number of anion transport inhibitors. These characteristics were identical to those of the HCO3(-)-dependent component of the swelling induced by high K+ levels in the medium. Other transmitters, namely 5-hydroxytryptamine, dopamine, and gamma-amino butyric acid, were ineffective. The effects of norepinephrine, histamine and 2-chloroadenosine were antagonised by propranolol and phentolamine, chlorpheniramine and diphenhydramine, and theophylline respectively. These antagonists also inhibited HCO3(-)-dependent, K+-stimulated swelling. The transmitters which induced swelling also stimulated the carbonic anhydrase activity of cerebrocortical slices. We conclude from these data that the HCO3(-)-dependent component of K+-stimulated swelling may be due to K+-stimulated release of transmitters. Furthermore, the fact that the transmitters which induce swelling have also been reported to be most effective in increasing cAMP content in both brain slices or cultured astrocytes is consistent with the swelling response being mediated via cAMP-induced changes and being predominantly localized to astrocytes.

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Engineering Ca²⁺-dependent DNA polymerase activity

Biggs

Paz

Bhan

et al. 2023

Preprint

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Advancements in synthetic biology have provided new opportunities in biosensing with applications ranging from genetic programming to diagnostics. Next generation biosensors aim to expand the number of accessible environments for measurement, increase the number of measurable phenomena, and improve the quality of the measurement. To this end, an emerging area in the field has been the integration of DNA as an information storage medium within biosensor outputs, leveraging nucleic acids to record biosensor state over time. However, slow signal transduction steps, due to the timescales of transcription and translation, bottleneck many sensing-DNA recording approaches. DNA polymerases (DNAPs) have been proposed as a solution to the signal transduction problem by operating as both the sensor and responder, but there is presently a lack of DNAPs with functional sensitivity to many desirable target ligands. Here, we engineer components of the Pol δ replicative polymerase complex of Saccharomyces cerevisiae to sense and respond to Ca2+, a metal cofactor relevant to numerous biological phenomena. Through domain insertion and binding site grafting to Pol δ subunits, we demonstrate functional allosteric sensitivity to Ca2+. Together, this work provides an important foundation for future efforts in developing DNAP-based biosensors.

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George M. Church

Stimulation of Carbonic Anhydrase Activity and Phosphorylation in Primary Astroglial Cultures by Norepinephrine

Swelling and ion uptake in cat cerebrocortical slices:

Engineering Ca²⁺-dependent DNA polymerase activity

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George M. Church

Stimulation of Carbonic Anhydrase Activity and Phosphorylation in Primary Astroglial Cultures by Norepinephrine

Swelling and ion uptake in cat cerebrocortical slices:

Engineering Ca2+-dependent DNA polymerase activity

Contact Info

Product

Resources

About

Engineering Ca²⁺-dependent DNA polymerase activity