EFFECTS OF GLUTAMINE DEPRIVATION ON GLUTAMINE TRANSPORT AND SYNTHESIS IN PRIMARY CULTURE OF RAT SKELETAL-MUSCLE

被引：19

作者：

TADROS, LB ^{[1
]}

WILLHOFT, NM ^{[1
]}

TAYLOR, PM ^{[1
]}

RENNIE, MJ ^{[1
]}

机构：

[1] UNIV DUNDEE,DEPT ANAT & PHYSIOL,DUNDEE DD1 4HN,SCOTLAND

来源：

AMERICAN JOURNAL OF PHYSIOLOGY | 1993年 / 265卷 / 06期

关键词：

MYOBLASTS; MYOTUBES; AMINO ACID TRANSPORT; GLUTAMINE SYNTHETASE; GLUTAMINASE; INSULIN;

D O I：

10.1152/ajpendo.1993.265.6.E935

中图分类号：

Q4 [生理学];

学科分类号：

071003 ;

摘要：

The effects of deprivation and supplementation of exogenous glutamine (0.06 and 2.2 mM in the culture medium, respectively) were studied in mononucleated myoblasts and in multinucleated myotubes. Myoblasts cultured in glutamine-deprived medium showed reductions in plating efficiency and myotube fusion index. Myotubes grown in glutamine-supplemented cultures had higher intracellular glutamine concentrations than those grown in glutamine-deprived medium (67 +/- 4.2 vs. 46 +/- 3.6 nmol/mg cell protein, respectively) and glutamine-supplemented myotubes utilized glutamine, whereas glutamine-deprived myotubes released it. Glutamine deprivation for 12 h caused a significant, cycloheximide-blockable increase in the capacity for glutamine uptake via system N(m) in both myoblasts and myotubes (maximum velocity increases of 23 +/- 5.3 and 35 +/- 4.2%, respectively), which was reversed by glutamine replenishment. Depriving myotubes of glutamine did not alter the kinetics of uptake of amino acid transport systems A, ASC, or L. Glutamine deprivation resulted in a threefold increase in glutamine synthetase activity, whereas glutaminase activity remained unchanged. System N(m) and glutamine synthetase appear to undergo adaptive upregulation in glutamine-deprived muscle cells to compensate for the reduced exogenous glutamine supply.

引用

页码：E935 / E942

页数：8

共 30 条

[1] INTER-ORGAN METABOLISM OF AMINO-ACIDS INVIVO [J].

ABUMRAD, NN ;

WILLIAMS, P ;

FREXESSTEED, M ;

GEER, R ;

FLAKOLL, P ;

CERSOSIMO, E ;

BROWN, LL ;

MELKI, I ;

BULUS, N ;

HOURANI, H ;

HUBBARD, M ;

GHISHAN, F .

DIABETES-METABOLISM REVIEWS, 1989, 5 (03) :213-226

[2]

ASKENAZI J, 1978, ANN SURG, V188, P797

[3] ROLE OF AMINO-ACID-TRANSPORT AND COUNTERTRANSPORT IN NUTRITION AND METABOLISM [J].

CHRISTENSEN, HN .

PHYSIOLOGICAL REVIEWS, 1990, 70 (01) :43-77

[4] EFFECT OF GLUTAMINE ON DEGRADATION OF GLUTAMINE-SYNTHETASE IN HEPATOMA TISSUE-CULTURE CELLS [J].

CROOK, RB ;

TOMKINS, GM .

BIOCHEMICAL JOURNAL, 1978, 176 (01) :47-52

[5] AMINO ACID METABOLISM IN MAMMALIAN CELL CULTURES [J].

EAGLE, H .

SCIENCE, 1959, 130 (3373) :432-437

[6] NEURAL CONTROL OF GLUTAMINE-SYNTHETASE ACTIVITY IN RAT SKELETAL-MUSCLES [J].

FENG, B ;

KONAGAYA, M ;

KONAGAYA, Y ;

THOMAS, JW ;

BANNER, C ;

MILL, J ;

MAX, SR .

AMERICAN JOURNAL OF PHYSIOLOGY, 1990, 258 (05) :E757-E761

[7] EFFECT OF DIABETES ON GLUTAMINE-SYNTHETASE EXPRESSION IN RAT SKELETAL-MUSCLES [J].

FENG, B ;

BANNER, C ;

MAX, SR .

AMERICAN JOURNAL OF PHYSIOLOGY, 1990, 258 (05) :E762-E766

[8] GLUTAMINE REGULATES GLUTAMINE-SYNTHETASE EXPRESSION IN SKELETAL-MUSCLE CELLS IN CULTURE [J].

FENG, B ;

SHIBER, SK ;

MAX, SR .

JOURNAL OF CELLULAR PHYSIOLOGY, 1990, 145 (02) :376-380

[9] REGULATION OF ASPARAGINE SYNTHETASE GENE-EXPRESSION BY AMINO-ACID STARVATION [J].

GONG, SS ;

GUERRINI, L ;

BASILICO, C .

MOLECULAR AND CELLULAR BIOLOGY, 1991, 11 (12) :6059-6066

[10] REGULATION OF AMINO-ACID TRANSPORT IN ANIMAL-CELLS [J].

GUIDOTTI, GG ;

GAZZOLA, GC ;

BORGHETTI, AF .

BIOCHIMICA ET BIOPHYSICA ACTA, 1978, 515 (04) :329-366

← 1 2 3 →