Characterizing Interaction Between PASK and PBP1/ ATXN2 to Regulate Cell Growth and Proliferation

Choksi, Nidhi Rajan

01 September 2016

Pbp1 is a component of glucose deprivation induced stress granules and is involved in P-body-dependent granule assembly. We have recently shown that Pbp1 plays an important role in the interplay between three sensory protein kinases in yeast: AMP-regulated kinase (Snf1 in yeast), PAS kinase 1 (Psk1 in yeast), and the target of rapamycin complex 1 (TORC1), to regulate glucose allocation during nutrient depletion. This signaling cascade occurs through the SNF1-dependent phosphorylation and activation of Psk1, which phosphorylates and activates poly(A)- binding protein binding protein 1 (Pbp1), which then inhibits TORC1 through sequestration at stress granules. In this study we further characterized the regulation of Pbp1 by PAS kinase through the characterization of the role of the Psk1 homolog (Psk2) in Pbp1 regulation, and the identification of functional Pbp1 binding partners. Human ataxin-2 (ATXN2) is the homolog of yeast Pbp1 and has been shown to play an important role in the development of several ataxias. In this study we have also provided the evidence that human ataxin-2 can complement Pbp1 in yeast, and that human PAS kinase can phosphorylate human ataxin-2. Further characterizing this interplay between PAS kinase and Pbp1/ATXN2 aid in understanding pathways required for proper glucose allocation during nutrient depletion, including reducing cell growth and proliferation when energy is low. In addition, it yields valuable insights into the role of ataxin-2 in the development of devastating ataxias.

nutrient sensing kinases

AMP regulated kinase (AMPK)

PAS kinase (PSK or PASK)

Target of Rapamycin (TOR)

Pbp1

Ataxin-2 (ATXN2)

Microbiology

Snf1 Mediated Phosphorylation and Activation of PAS Kinase

Badal, Bryan D.

01 September 2014

Nutrient sensing kinases sense available nutrients and regulate cell activity accordingly. Three of these enzymes are AMP regulated kinase (AMPK, or Snf1 in yeast), PAS kinase, and target of rapamycin (TOR), are conserved from yeast to man and have overlapping function. AMPK and Snf1 are important in sensing when nutrient status in the cell is low and down regulating energy consuming pathways. PAS kinase is required for glucose homeostasis in the cell, and responds to glucose levels. TOR senses nutrients such as amino acids and upregulates cell growth pathways primarily through protein synthesis. Due to the varying nature of these enzymes, cross talk is expected in order for the cell to properly regulate cellular metabolism and growth in response to energy and nutrient availability. Previous studies have shown that activation of yeast PAS kinase under nutrient stress conditions requires the presence of Snf1. The aim of this thesis is to determine whether Snf1 directly phosphorylates and activates PAS kinase through both in vivo and in vitro approaches. PAS kinase was found to require Snf1 for both activation and phosphorylation in vivo. In vitro kinase assays were also performed to confirm a direct phosphorylation event. The results from this study support the direct phosphorylation and activation of PAS kinase by Snf1, linking cellular energy status to glucose allocation.

nutrient sensing kinases

target of rapamycin (TOR)

AMP regulated kinase (AMPK)

PAS kinase (PSK or PASK)

Osh7

cellular metabolism

Microbiology

Evolution and Selection: From Suppression of Metabolic Deficiencies to Bacteriophage Host Range and Resistance

Arens, Daniel Kurt

14 April 2021

The evolution and adaptation of microorganisms is so rapid it can be seen in the time frame of days. The root cause for their evolution comes from selective environmental pressures that see organisms with beneficial mutations survive otherwise deadly encounters or outperform members of its population who fail to adapt. This does not always result in strict improvement of the individual as in the case of antibiotic resistant bacteria who often display fitness tradeoffs to avoid death (see Reviews [1-3]). For example, when an ampicillin resistance gene (ampC) containing plasmid that is occasionally found in the wild was transformed into S. typhimurium the bacteria had slower growth and impaired invasiveness [4]. In another example, capreomycin use with mycobacteria resulted in lower binding of the drug to the ribosome through mutations in rRNA methylase TlyA 16S rRNA, which decreases the overall fitness of the mycobacteria [5]. The evolutionary interactomes between bacteria and antibiotics do not end there, as antibiotic resistant bacteria often accumulate compensatory mechanisms to regain fitness. These range in effect with some altering individual cellular pathways and others having systemic affects [1]. My work has focused on the intersection of diabetes and related antibiotic resistant bacterial infections. Diabetes is one of the leading health issues in the United States, with over 10% of the adult population and over 26% of the elderly diagnosed (American Diabetes Association) [6]. Herein I further characterize the molecular pathways involved in diabetes, through the study of PAS kinase (PASK) function. PAS kinase is a serine-threonine protein kinase which regulates the pathways disrupted in diabetes, namely triglyceride accumulation, metabolic rate (respiration), adiposity and insulin production and sensitivity [7-9]. In this study I specifically focus on the effects of PAS kinase and its substrate, USF1/Cbf1p, and how their altered metabolic deficiencies can be suppressed using yeast cells. Through this study I further characterized the molecular function of USF1/Cbf1p through the identification of putative co-transcriptional regulators, identify novel genes involved in the regulation of respiration, and uncover a function or a previous uncharacterized protein, Pal1p. Part of the diabetes healthcare challenge results from the wide range of diseases that are associated with diabetes, including obesity [10, 11], renal failure [12, 13], neuropathies and neurodegeneration [14, 15], endocrine dysfunctions [16, 17], and cancers [18]. In addition, diabetes is a leading cause of lower limb amputations, due to poor circulation and the prevalence of ulcers [19-21], many of which are antibiotic resistant [22-25]. Phage therapy, based on the administration of bacterial viruses, is a viable option for the treatment of these diseases, with our lab recently isolating bacteriophages for several clinical cases. In the second half of my thesis, I present the study of the adaptation of bacteriophages to their hosts as well as report contributions of local ecology to their evolution.

Diabetes

cellular respiration

mitochondria

metabolism

CBF1

USF1

PAL1

oxidative phosphorylation

mitophagy

yeast

PASK

bacteriophage

phage

phage therapy

antibiotic resistance

evolution

Klebsiella

Erwinia

Life Sciences

Rôle de l’enzyme PAS kinase dans la régulation du facteur de transcription PDX-1 dans la cellule bêta pancréatique

Semache, Meriem

12 1900

No description available.

Diabète

Glucose

Palmitate

Cellule bêta pancréatique

Gène de l'insuline

îlot de Langerhans

PDX-1

PASK

GSK3b

ERK1/2

PKB

Diabetes

Glucose

Palmitate

Pancreatic beta cell

Islet of Langerhans