Stimulus-response coupling in smooth muscle

Simpson, Alec William Michael

January 1989

No description available.

572

Smooth muscle activation

Cellular events underlying endothelin-1-induced contraction of renal arteries

Betts, Luisa C.

January 2000

No description available.

612

Smooth muscle

The influence of oxygen on the isolated human umbilical artery

MacLennan, Stephen John

January 1986

No description available.

612

Smooth muscle sensitivity

pH and vascular tone

Ighoroje, Ahbor Dolly Awani

January 1987

No description available.

590

Vascular smooth muscle

Deformation quantisation in singular spaces

Maldonado-Mercado, César

January 2003

No description available.

514

Smooth ambient manifold

Stimulation of the mitogen-activated protein kinase (MAPK) pathway in DDT₁MF-2 cells by adenosine A₁ receptors and histamine H₁ receptors

Robinson, Alexander John

January 2002

No description available.

612

Smooth muscle

The Role of the Transcription Factor nFAT in the Regulation of Smooth Muscle Contractility

Layne, Jeff

09 June 2008

The goals of this dissertation were to explore the role of the Ca2+-sensitive transcription factor NFAT in the regulation of smooth muscle contractility. We have identified a conserved NFAT binding site that overlaps an intronic SRF-binding CArG element that has previously been demonstrated to be essential for expression of smooth muscle α-actin. Transfection of a reporter construct containing the composite CArG/NFAT element, designated SNAP, into SMCs resulted in robust basal reporter activity that was sensitive to the calcineurin/NFAT pathways inhibitors FK506 and CsA. Mutations to either the NFAT or adjacent SRF binding site essentially abolished reporter activity, indicating that both were required. Co-immunoprecipitation assays revealed that NFATc3 and SRF formed a complex in solution, and that the formation of this complex was facilitated by the presence of the SNAP oligonucleotide. Inhibition of the calcineurin-NFAT pathway decreased α-actin expression in cultured SMCs, suggesting that NFAT plays a role in the expression of smooth muscle contractile proteins such as α-actin. To determine if NFAT transcriptional activity is involved in modulating urinary bladder smooth muscle contractility, we compared the contractile and electrophysiological properties of NFATc3-null mice to wild-type mice. UBSM strips taken from NFATc3-null mice displayed an elevated contractile response to EFS compared to strips from wild-type mice. This increased contractility was due to a decrease in IBTX-sensitive BK current and was supported at the molecular level by reduced expression of mRNA for the pore-forming α-subunit of the BK channel. Single-channel recordings revealed that the β-subunit of the BK channel, which modulates the sensitivity of the BK channel to voltage and Ca2+, was not altered. Interestingly, TEA-sensitive KV currents, and expression of the pore-forming KV2.1 subunit, were increased in the NFATc3-null myocytes. However, the increased contractile response of UBSM strips from NFATc3-null mice indicates that, at least in response to electrical field stimulation, the downregulation of BK current plays a more significant role than does the increase in KV current. Presumably, this is due to the prominent role that BK channels play in shaping the UBSM action potential. Thus, this dissertation provides evidence that NFAT plays a role in modulating smooth muscle contractility via its role in regulating the expression of contractile proteins and ion channels and, furthermore, lays the foundation for future investigations into the specific role of NFAT in the pathological response of the urinary bladder to outlet obstruction.

Smooth muscle

NFAT

The invasion of Smooth cordgrass (Spartina alterniflora) in China : risk assessment using spatial modeling

Zhang, Jinghan

January 2012

Smooth cordgrass (Spartina alterniflora) is one of the harmful quarantine weeds in China. Since its first introduction in China in 1979, this alien species has spread rapidly and damaged local ecological environments. Research to predict a suitable new area is an important step for management of the species and to prevent a further spread. In this study, Spartina alterniflora’s ecological niche was modeled using the application MAXENT. Analysis was based on species’ current distribution. The investigations of this study were two-fold. First, a large-scale global investigation (outside China) was conducted to predict suitable areas in China by comparing global and Chinese records of the species. In the second set, the combined records were used to predict suitable areas in the Jiangsu Province. The model’s accuracy was evaluated by Receiver Operator Characteristic (ROC) curve. The areas under the ROC curve (AUC value) were all over 0.95, which indicated high predictive ability of this model. In the large scale prediction, Shanghai, Zhejiang, Fujian, Guangzhou, Guangxi and southern part of Wuhan, Jiangsu and Anhui were all potentially endangered by S. alterniflora invasion. On the smaller scale, the prone to invasion areas were mostly concentrated on southern part and some coastal areas of Jiangsu Province, where the precipitation and temperature were appropriate for this grass. Because of S. alterniflora has high dispersal ability and human induced history, the potential distribution areas in China are considerable and it may invade more areas, in result spreading faster in the future. To prevent further invasion and spread, an early eradication program should be adopted in the newly invaded areas. Meanwhile, the monitoring programs should also need to be applied in potential survival areas, especially in coastal harbors, airports, and tourism areas which are highly vulnerable to S. alterniflora invasion.

prediction

Smooth cordgrass

Maxent

none

Liao, Yuan-hung

31 May 2002

none

Smooth Transition Autoregressive Model

Characterization of heparin receptor signal transduction in vascular smooth muscle cells /

Gilotti, Albert C.

January 2000

Thesis (Ph. D.)--Lehigh University, 2000. / Includes vita. Includes bibliographical references (leaves 120-150).

Heparin. Vascular smooth muscle.