Učinek glukoze in z AMP aktivirane protein kinaze na izražanje podenot Na+,K+-ATPaze v skeletnomišičnih celicah

Vidović, Anja

Učinek glukoze in z AMP aktivirane protein kinaze na izražanje podenot Na+,K+-ATPaze v skeletnomišičnih celicah
ID Vidović, Anja (Avtor), ID Pirkmajer, Sergej (Mentor) Več o mentorju... Povezava se odpre v novem oknu

, ID Chibalin, Alexander (Komentor)

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Izvleček

CILJI: Glavni cilj raziskave je bil ugotoviti, ali in kako razpoložljivost glukoze in AMPK vplivata na izražanje podenot Na+,K+-ATPaze (NKA) v kulturah skeletnomišičnih celic. Specifični cilji so bili: (1) določiti, ali glukoza vpliva na izražanje specifičnih izooblik podenot NKA; (2) odkriti transkripcijske faktorje, ki sodelujejo pri uravnavanju izražanja podenot NKA preko glukoze; (3) opredeliti pomen aktivacije AMPK pri uravnavanju izražanja podenot NKA. HIPOTEZE: Preverili smo naslednje tri hipoteze: (H1) Glukoza uravnava izražanje specifičnih izooblik podenot NKA v skeletnomišičnih celicah. (H2) Na glukozo občutljivi transkripcijski faktorji vplivajo na izražanje podenot NKA v skeletnomišičnih celicah. (H3) AMPK uravnava vsebnost podenot NKA v skeletnomišičnih celicah. METODE: Poskuse smo izvedli na standardnih modelih, ki se uporabljajo za raziskave skeletnih mišic in vitro: podganje L6 skeletnomišične celične linije in primarne kulture človeških skeletnomišičnih celic (HSMC). Izražanje podenot NKA smo ocenili z uporabo kvantitativne reakcije s polimerazo v realnem času (qPCR) in odtisom western. Za oceno vloge AMPK pri uravnavanju NKA smo uporabili utišanje genov. REZULTATI: Ad H1: Da bi raziskali vpliv glukoze na izražanje podenot NKA, smo izvedli poskuse na podganjih L6 celicah in HSMC pri različnih koncentracijah glukoze (0 mM, 5,5 mM in 25 mM). V celicah L6 je pomanjkanje glukoze zvečalo izražanja NKA?1 in NKA?2 na ravni proteinov, s podobnimi spremembami na ravni NKA?1 mRNA. Nasprotno pa se je izražanje NKA?2 mRNA v odsotnosti glukoze zmanjšalo. V HSMC se je raven proteinov NKA?1 povečala pri visoki glukozi, medtem ko je NKA?2 ostala nespremenjena. Ad H2: Tretiranje podganjih mišičnih cevčic s 5,5 mM koncentracijo glukoze je v primerjavi s pomanjkanjem glukoze in visoko koncentracijo glukoze zvečalo izražanja proteina Sp1 in proteina ZEB1 na ravni mRNA. Po drugi strani pa je tretiranje podganjih cevčic s 25 mM koncentracijo glukoze znižalo izražanje Mondo A in proteina ATF1 na ravni mRNA. ATF1 je bil znižan tudi pri koncentraciji glukoze 5,5 mM. Poleg tega je pomanjkanje glukoze znižalo izražanje proteina REST na ravni mRNA, tako pri koncentraciji glukoze 5,5 mM kot 25 mM. Pri HSMC je bila edina pomembna razlika v izražanju mRNA kot odziv na različne koncentracije glukoze opažena pri ChREBP, ki se je v odstotnosti glukoze povečala. Ad H3: L6 mišične cevčice smo 24 ur tretirali z AICAR in A-769662. Aktivatorja AMPK sta zmanjšala vsebnost proteinov NKA?1 in NKA?2, kar je bilo skladno z izražanjem na ravni mRNA. Prav tako smo z aktivatorji AMPK zaznali zmanjšano izražanje FXYD1 na ravni mRNA. Da bi raziskali vpliv AMPK na NKA, smo na L6 cevčicah utišali gena AMPK?1/?2 in kot rezultat se je raven proteina NKA?1 povečala pri koncentraciji glukoze 5,5 mM. V odsotnosti glukoze se je raven proteina NKA?2 zmanjšala po utišanju AMPK?1/?2. Pri HSMC je bilo izražanje NKA?1 mRNA v utišanih celicah AMPK?1/?2 povečano pri koncnetraciji glukoze 5,5 mM, skupaj z zmanjšanjem NKAß1 in NKAß2 mRNA. ZAKLJUČKI: (1) Glukoza uravnava izražanje specifičnih izooblik podenot NKA v celicah L6 in HSMC, kar potrjuje našo prvo hipotezo. (2) Naša raziskava posredno nakazuje, da je izražanje mRNA nekaterih transkripcijskih dejavnikov (Sp1, ZEB1, ATF1 in REST v L6 celicah in ChREBP v HSMC) odzivno na glukozo, kar ima lahko vlogo pri vplivu na izražanje podenot NKA v skeletnomišičnih celicah. Naše druge hipoteze ne moremo niti potrditi niti zavreči. (3) V celicah L6, AMPK uravnava podenote NKA na ravni proteinov in mRNA, z načinom, odvisnim od posamezne izooblike. Poleg tega je AMPK negativni regulator FXYD1 v celicah L6. Naši rezultati podpirajo tretjo hipotezo.

Jezik:	Slovenski jezik
Ključne besede:	Na+, K+-ATPaza, glukoza, AMPK, skeletnomišične celice, energijski stres
Vrsta gradiva:	Doktorsko delo/naloga
Organizacija:	MF - Medicinska fakulteta
Leto izida:	2024
PID:	20.500.12556/RUL-159216
Datum objave v RUL:	04.07.2024
Število ogledov:	19
Število prenosov:	1
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Sekundarni jezik

Izvleček:
Jezik:	Angleški jezik
Naslov:	The effect of glucose and AMP-activated protein kinase on expression of Na+,K+-ATPase subunits in skeletal muscle cells
AIMS: The overarching aim of our study was to establish whether and how glucose availability and AMPK affect expression of Na+,K+-ATPase (NKA) subunits in cultured skeletal muscle cells. Specific aims were: (1) to determine if glucose affects expression of NKA subunits in isoform-specific manner; (2) to uncover transcription factors involved in regulation of NKA subunit expression by glucose; (3) to dissect the role of AMPK activation in regulation of NKA subunit expression. HYPOTHESES: We tested three hypotheses: (H1) Glucose regulates expression of NKA subunits in isoform specific-manner in skeletal muscle cells. (H2) Glucose-sensitive transcription factors modulate expression of NKA subunits in skeletal muscle cells. (H3) AMPK regulates the abundance of NKA subunits in skeletal muscle cells. METHODS: Experiments were performed on standard models used for skeletal muscle research in vitro: rat L6 skeletal muscle cell line and primary human skeletal muscle cells (HSMCs). Expression of NKA subunits was estimated using quantitative polymerase chain reaction (qPCR) and Western Blot. Gene silencing was used to assess the role of AMPK in regulation of NKA. RESULTS: Ad H1: To investigate the effects of glucose on NKA expression and protein abundance, we performed experiments in rat L6 cells and HSMCs under different glucose concentrations (0 mM, 5.5 mM and 25 mM). In L6 cells, glucose deprivation led to an increase in protein levels of NKAα1 and NKAα2, and the trend of mRNA expression was consistent with the results of protein expression of NKAα1. Conversely, the mRNA expression of NKAα2 was downregulated in glucose-free media. In HSMCs, NKAα1 protein levels increased under high glucose, while NKAα2 remained unchanged. Ad H2: Treating rat L6 myotubes with glucose concentration of 5.5 mM resulted in upregulation of mRNA of Sp1 and ZEB1 compared to glucose deprivation and high glucose concentration. On the other hand, Mondo A and ATF1 were downregulated after treatment with a glucose concentration of 25 mM. ATF1 was also downregulated at a glucose concentration of 5.5 mM. In addition, glucose deprivation downregulated mRNA expression of REST at both 5.5 mM and 25 mM glucose concentrations. In HSMCs, the only significant difference mRNA expression in response to different glucose concentrations was observed for ChREBP, which was upregulated under glucose-free conditions. Ad H3: L6 myotubes were treated with AICAR and A-769662 for 24 hours. AMPK activators decreased the protein abundance of NKAα1 and NKAα2, consistent with mRNA expression. We also detected decreased mRNA expression of FXYD1 after treatment with AMPK activators. To investigate the involvement of AMPK in NKA regulation, knock-down of AMPKα1/α2 was performed in L6 myotubes, and the protein abundance of NKAα1 was increased at a glucose concentration of 5.5 mM. Furthermore, knock-down of AMPKα1/α2 resulted in decreased protein abundance of NKAα2 under glucose deprivation. In HSMCs, at a glucose concentration of 5.5 mM, mRNA expression of NKAα1 was upregulated in AMPKα1/α2 knockdown cells, along with downregulation of mRNA expression of NKAβ1 and NKAβ2. CONCLUSIONS: (1) Glucose affects the expression of NKA subunits in L6 cells and HSMCs in an isoform-specific manner, supporting our first hypothesis. (2) Our study indirectly suggests that mRNA expression of some transcription factors (Sp1, ZEB1, ATF1 and REST v L6 cells and ChREBP in HSMCs) is glucose-responsive and may play a role in influencing the expression of NKA subunits in skeletal muscle cells. We can neither confirm nor reject our second hypothesis. (3) In L6 cells, AMPK regulates protein and mRNA levels of NKA subunits in an isoform-dependent manner. Furthermore, we indicate that AMPK is a negative regulator of FXYD1 in L6 cells. Overall, our results support the third hypothesis.
Ključne besede:	Na+, K+-ATPase, glucose, AMPK, skeletal muscle cells, energy stress

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