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Target Concepts:
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Query: UMLS:C0392674 (
exhaustion
)
13,658
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Glycogenolysis results in the selective catabolism of individual glycogen granules by glycogen phosphorylase. However, once the carbohydrate portion of the granule is metabolized, the fate of
glycogenin
, the protein primer of granule formation, is not known. To examine this, male subjects (n = 6) exercised to volitional
exhaustion
(Exh) on a cycle ergometer at 75% maximal O2 uptake. Muscle biopsies were obtained at rest, 30 min, and Exh (99 +/- 10 min). At rest, total glycogen concentration was 497 +/- 41 and declined to 378 +/- 51 mmol glucosyl units/kg dry wt following 30 min of exercise (P < 0.05). There were no significant changes in proglycogen, macroglycogen,
glycogenin
activity, or mRNA in this period (P > or = 0.05). Exh resulted in decreases in total glycogen, proglycogen, and macroglycogen as well as
glycogenin
activity (P < 0.05). These decrements were associated with a 1.9 +/- 0.4-fold increase in
glycogenin
mRNA over resting values (P < 0.05). Glycogenolysis in the initial exercise period (0-30 min) was not adequate to induce changes in
glycogenin
; however, later in exercise when concentration and granule number decreased further, decrements in
glycogenin
activity and increases in
glycogenin
mRNA were demonstrated. Results show that
glycogenin
becomes inactivated with glycogen catabolism and that this event coincides with an increase in
glycogenin
gene expression as exercise and glycogenolysis progress.
...
PMID:Glycogenin activity and mRNA expression in response to volitional exhaustion in human skeletal muscle. 1586 Jun 84
Glycogenin is the self-glycosylating protein primer that initiates glycogen granule formation. To examine the role of this protein during glycogen resynthesis, eight male subjects exercised to
exhaustion
on a cycle ergometer at 75% Vo2 max followed by five 30-s sprints at maximal capacity to further deplete glycogen stores. During recovery, carbohydrate (75 g/h) was supplied to promote rapid glycogen repletion, and muscle biopsies were obtained from the vastus lateralis at 0, 30, 120, and 300 min postexercise. At time 0, no free (deglycosylated)
glycogenin
was detected in muscle, indicating that all
glycogenin
was complexed to carbohydrate. Glycogenin activity, a measure of the glycosylating ability of the protein, increased at 30 min and remained elevated for the remainder of the study. Quantitative RT-PCR showed elevated
glycogenin
mRNA at 120 min followed by increases in protein levels at 300 min. Glycogenin specific activity (
glycogenin
activity/relative protein content) was also elevated at 120 min. Proglycogen increased at all time points, with the highest rate of resynthesis occurring between 0 and 30 min. In comparison, macroglycogen levels did not significantly increase until 300 min postexercise. Together, these results show that, during recovery from prolonged exhaustive exercise,
glycogenin
mRNA and protein content and activity increase in muscle. This may facilitate rapid glycogen resynthesis by providing the
glycogenin
backbone of proglycogen, the major component of glycogen synthesized in early recovery.
...
PMID:Increases in glycogenin and glycogenin mRNA accompany glycogen resynthesis in human skeletal muscle. 1653 52
To determine whether preexercise muscle glycogen content influences the transcription of several early-response genes involved in the regulation of muscle growth, seven male strength-trained subjects performed one-legged cycling exercise to
exhaustion
to lower muscle glycogen levels (Low) in one leg compared with the leg with normal muscle glycogen (Norm) and then the following day completed a unilateral bout of resistance training (RT). Muscle biopsies from both legs were taken at rest, immediately after RT, and after 3 h of recovery. Resting glycogen content was higher in the control leg (Norm leg) than in the Low leg (435 +/- 87 vs. 193 +/- 29 mmol/kg dry wt; P < 0.01). RT decreased glycogen content in both legs (P < 0.05), but postexercise values remained significantly higher in the Norm than the Low leg (312 +/- 129 vs. 102 +/- 34 mmol/kg dry wt; P < 0.01). GLUT4 (3-fold; P < 0.01) and
glycogenin
mRNA abundance (2.5-fold; not significant) were elevated at rest in the Norm leg, but such differences were abolished after exercise. Preexercise mRNA abundance of atrogenes was also higher in the Norm compared with the Low leg [atrogin: approximately 14-fold, P < 0.01; RING (really interesting novel gene) finger: approximately 3-fold, P < 0.05] but decreased for atrogin in Norm following RT (P < 0.05). There were no differences in the mRNA abundance of myogenic regulatory factors and IGF-I in the Norm compared with the Low leg. Our results demonstrate that 1) low muscle glycogen content has variable effects on the basal transcription of select metabolic and myogenic genes at rest, and 2) any differences in basal transcription are completely abolished after a single bout of heavy resistance training. We conclude that commencing resistance exercise with low muscle glycogen does not enhance the activity of genes implicated in promoting hypertrophy.
...
PMID:Influence of preexercise muscle glycogen content on transcriptional activity of metabolic and myogenic genes in well-trained humans. 1721 24
Glycogenin initiates the biosynthesis of proteoglycogen, the mammalian
glycogenin
-bound glycogen, by intramolecular autoglucosylation. The incubation of
glycogenin
with UDP-glucose results in formation of a tyrosine-bound maltosaccharide, reaching maximum polymerization degree of 13 glucose units at cessation of the reaction. No
exhaustion
of the substrate donor occurred at the autoglucosylation end and the full autoglucosylated enzyme continued catalytically active for transglucosylation of the alternative substrate dodecyl-maltose. Even the autoglucosylation cessation once
glycogenin
acquired a mature maltosaccharide moiety, proteoglycogen and
glycogenin
species ranging rM 47-200kDa, derived from proteoglycogen, showed to be autoglucosylable. The results describe for the first time the ability of polysaccharide-bound
glycogenin
for intramolecular autoglucosylation, providing evidence for cessation of the glucose polymerization initiated into the tyrosine residue, by inaccessibility of the acquired maltosaccharide moiety to further autoglucosylation.
...
PMID:Evidence for glycogenin autoglucosylation cessation by inaccessibility of the acquired maltosaccharide. 1867 43
