Relationships between proteasomes and viral gene products.

The interrelationships between proteasomes and viral gene products are very complex. 20S proteasomes associate with a number of viral mRNAs which are cleaved by proteasome's associated endonuclease activity. In addition proteasome's endopeptidase activities are involved in the presentation of viral antigens. Viral proteins of different origin associate with the 20S and 26S complexes and interfere with their enzymatic activities. A major part of this review deals with the interactions between 20S proteasomes and the gene products of the human immunodeficiency virus (HIV) which has been studied in detail by our group.

Proteasome (prosome) associated endonuclease activity.

The 20S proteasome (prosome) is a highly organized multiprotein complex with approximate molecular weight of about 700 kDa. Whilst the role of the proteasome in the processing and turnover of cellular proteins is becoming clearer, its relationship with RNA remains still obscure. Here we focus on the nature and function of proteasome associated endonuclease activity. Thus the involvement of a proteasome alpha-type subunit in RNA-degradation, the catalytic requirements, the interaction of proteasomes with their RNA-substrate and the identification of a well defined cleavage site in the 3'UTR of short-lived cellular mRNAs will be described in detail. All data indicate that proteasomes associated endonuclease activity could be involved in post-transcriptional gene control at the level of translation.

Relationships between proteasomes and RNA.

The 20S proteasome (prosome) is a highly organized multi-protein complex with approximate molecular weight of about 700 kDa. Whilst the role of the proteasome in the processing and turnover of cellular proteins is becoming clearer, its relationship with RNA remains obscure. Over the last decade the possibility of association of proteasomes with specific RNAs or mRNPs have been particularly controversial. Proteasomes were reported to inhibit translation of viral mRNAs and to be tightly associated with RNase activity. It is possible that proteasomes are also involved in cellular RNA breakdown and RNA processing like prokaryotic RNase E.

Metabolic and contractile differentiation of rabbit muscles during growth.

1. A study was carried out of post-natal evolution of the oxidative, glycolytic and contractile capacities in various types of rabbit muscle. 2. At birth, muscles are non-differentiated and present very limited metabolic and contractile activity, metabolism is mainly oxidative in all muscles. 3. Although muscular discrimination is manifest from the sixth week after birth, the glycolytic metabolism reaches its maximum capacity only after six to eight weeks. 4. Subsequently, oxidative metabolic capacity steadily decreases until adulthood.

Glycosylation and deglycosylation of proteasomes (prosomes) from calf-liver cells: high abundance of neuraminic acid.

Proteasomes (prosomes) of calf-liver cells were probed with three different biotinylated lectins: Limulus polyphemus agglutinin (LPA), specific for neuraminic acid; Solanum tuberosum agglutinin (STA), specific for GlcNac; and concanavalin A (Con A), specific for Man/Glc. While only one proteasomal protein reacted with STA, most of the proteasomal proteins reacted with LPA and several with Con A. Deglycosylation with N-glycosidase F showed that the detected glycan residues were asparagine-linked. Finally we demonstrate an alternative method for the isolation of proteasomes based on the affinity of certain proteasomal proteins to Con A.

Comparison of muscle phosphofructokinase from euthermic and hibernating Jaculus orientalis. Purification and determination of the quaternary structure.

1. The structural properties of skeletal muscle phosphofructokinase from euthermic and hibernating jerboa were compared. 2. The enzyme was purified by a rapid procedure; suspended in ammonium sulfate in the presence of ATP, it was found to be stable for three weeks. 3. A specific activity of 76 U/mg and at most 65 U/mg was obtained for the enzyme from the euthermic and hibernating jerboa, respectively. 4. The molecular weight was estimated to be 320 kDa for the oligomer and 80 kDa for the subunit. 5. A unique alanine residue was found at the C-terminal end, suggesting that the enzyme is a tetramer made of four identical subunits. 6. The tetrameric structure of phosphofructokinase was confirmed by using crosslinking with disuccinimidyl esters. 7. The kinetics of formation of the different crosslinked species were found to be in agreement with a model of the tetramer corresponding to a dihedral symmetry with isologuous contacts between protomers. 8. The same molecular characteristics and immunochemical properties were found for the enzyme extracted from the euthermic and hibernating animals.

Regulation of the skeletal muscle metabolism during hibernation of Jaculus orientalis.

1. The glycolytic flow in the skeletal muscle was considerably depressed during hibernation of Jaculus orientalis. 2. Although the ATP content was not modified, the ATP/AMP ratio was twice as large than under homeothermic conditions. 3. Furthermore, the hexose phosphates were markedly depressed. 4. The total activities of the key enzymes, hexokinase, phosphofructokinase and pyruvate kinase, which are regulated through the adenylates, decreased. 5. Under in vivo conditions, taking into account the small amount of fructose-6-phosphate and the ATP/AMP ratio, it is likely that phosphofructokinase was totally inhibited, explaining the undetectable amount of fructose 1.6 bisphosphate.