Effect of INF1 protein on anionic peroxidase genes in tobacco leaves during the Hypersensitive Response

Su, Ying-Chang

18 August 2005

none

peroxidase

INF1

Effect of INF1 Protein on Cationic Peroxidase Genes in Tobacco Leaves during Hypersensitive Response

Chen, Chou-Wei

15 July 2005

In our investigation, fully expanded tobacco leaves were used to study the hypersensitive response caused by the inoculation of INF1 purified from E. coli strains DH5£\

hypersensitive response

lignin

hydrogen

INF1

tobacco

Effect of INF1 on Lignin Biosynthesis in Tobacco Leaves during the Hypersensitive Response

Wang, Li-Ting

05 June 2004

Infection of fully expanded leaves of tobacco with INF1 causes the appearance of HR lesions within 12 h and progressive to all infection sites after 48 h treatment. Among the POD isozymes, the increase of cationic PODs and anionic PODs is correlated with the rise of lignin contents in INF1-treated leaves, especially cationic PODs (pI 9.5, pI 8.7, pI 8.3, pI 7.8, pI 7.4). It was suggested that the induction of POD activity resulted in part of H2O2 reduction. The increase of cationic (pI 9.5) and anionic (pI 4.4) POD transcripts was correlated with the increased cationic and anionic PODs activity in INF1-treated leaves. Therefore, the increased POD activity is due to the de novo synthesis of the cationic (pI 9.5) and anionic (pI 4.4) PODs in INF1-treated leaves. The increase in cationic pI 9.6 laccase transcript was also correlated with the increased cationic laccase activity in INF1-treated leaves. Our results suggest that laccase might play a major role on lignin biosynthesis at the early stage (6 h), and as the inoculation time was prolonged, peroxidases (especially cationic POD) and laccases will work together on lignin biosynthesis.

lignin

hydrogen peroxide

peroxidase

INF1

tobacco

laccase.

hypersensitive response

Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2)

Kulacz, Wojciech

30 April 2012

The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation.

formins

Inverted Formin-1 (INF1)

actin

microtubules

primary cilium

Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2)

Kulacz, Wojciech

30 April 2012

The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation.

formins

Inverted Formin-1 (INF1)

actin

microtubules

primary cilium

Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2)

Kulacz, Wojciech

January 2012

The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation.

formins

Inverted Formin-1 (INF1)

actin

microtubules

primary cilium