Proteolysis by calpains: a possible contribution to degradation of p53.

p53 is a short-lived transcription factor that is frequently mutated in tumor cells. Work by several laboratories has already shown that the ubiquitin-proteasome pathway can largely account for p53 destruction, at least under specific experimental conditions. We report here that, in vitro, wild-type p53 is a sensitive substrate for milli- and microcalpain, which are abundant and ubiquitous cytoplasmic proteases. Degradation was dependent on p53 protein conformation. Mutants of p53 with altered tertiary structure displayed a wide range of susceptibility to calpains, some of them being largely resistant to degradation and others being more sensitive. This result suggests that the different mutants tested here adopt slightly different conformations to which calpains are sensitive but that cannot be discriminated by using monoclonal antibodies such as PAb1620 and PAb240. Inhibition of calpains by using the physiological inhibitor calpastatin leads to an elevation of p53 steady-state levels in cells expressing wild-type p53. Conversely, activation of calpains by calcium ionophore led to a reduction of p53 in mammalian cells, and the effect was blocked by cell-permeant calpain inhibitors. Cotransfection of p53-null cell lines with p53 and calpastatin expression vectors resulted in an increase in p53-dependent transcription activity. Taken together, these data support the idea that calpains may also contribute to the regulation of wild-type p53 protein levels in vivo.

Differential sensitivity of FOS and JUN family members to calpains.

Degradation of c-fos protein (c-FOS) in the cytoplasm is very rapid in vivo and constitutes a crucial regulation of the nuclear steady-state level through the control of the amount of full-length molecules available for nuclear transport. Using cytoplasmic extracts from various origins, we report herein that c-FOS degradation can be initiated in a calcium-dependent manner which involves cysteine proteases called milli- and micro-calpain. Interestingly, FOS-B, a member of the fos multigene family, as well as all members of the jun family (JUN-B, c-JUN and JUN-D) are also sensitive to calpains albeit to different extents. FRA-2, which is a c-FOS-related protein, is resistant to micro- but not to milli-calpain whereas FRA-1, another member of the fos family, is resistant to both proteases. Given the fact that a work by others (Hiraï et al., 1991b) suggests that calpains can be involved in c-FOS and c-JUN degradation in vivo, our observations raises the possibility of a novel contribution to the regulation of AP-1 transcription complex activity through a differential control of the steady-state level of some of its components that involves calpains.

Early functional glutamate receptors in acutely dissociated embryonic raphe cells.

We report for the first time, modulation of cytosolic calcium in response to glutamate and specific glutamate receptor agonists in early embryonic rat brain cells (raphe cells taken at gestation days 13 or 14). Metabotropic as well as ionotropic agonists were effective. Cells responding to kainic acid were particularly prominent in caudal raphe. We used very short post-plating delays (2 to 6 h); it may therefore be assumed that functional receptors already exist in the intact embryonic brain by gestation day 13. Since many developmental processes are influenced by cytosolic calcium modulation, glutamate receptors may play a key role in brain development, well before the extensively studied postnatal peak in receptor density.

Decreased susceptibility to calpains of v-FosFBR but not of v-FosFBJ or v-JunASV17 retroviral proteins compared with their cellular counterparts.

The c-Fos and c-Jun transcription factors are rapidly turned over in vivo. One of the multiple pathways responsible for their breakdown is probably initiated by calpains, which are cytoplasmic calcium-dependent cysteine proteases. The c-fos gene has been transduced by two murine oncogenic retroviruses called Finkel-Biskis-Jenkins murine sarcoma virus (FBJ-MSV) and Finkel-Biskis-Reilly murine sarcoma virus (FBR-MSV); c-jun has been transduced by the chicken avian sarcoma virus 17 (ASV17) retrovirus. Using an in vitro degradation assay, we show that the mutated v-FosFBR, but not v-FosFBJ or v-JunASV17, is resistant to calpains. This property raises the interesting possibility that decreased sensitivity to calpains might contribute to the tumorigenic potential of FBR-MSV by allowing greater accumulation of the protein that it encodes in infected cells. It has also been demonstrated that resistance to cleavage by calpains does not result from mutations that have accumulated in the Fos moiety of the viral protein but rather from the addition of atypical peptide motifs at its both ends. This observation raises the interesting possibility that homologous regions in viral and cellular Fos either display slightly different conformations or are differentially accessible to interacting proteins.

Ubiquitinylation is not an absolute requirement for degradation of c-Jun protein by the 26 S proteasome.

Degradation of rapidly turned over cellular proteins is commonly thought to be energy dependent, to require tagging of protein substrates by multi-ubiquitin chains, and to involve the 26 S proteasome, which is the major neutral proteolytic activity in both the cytosol and the nucleus. The c-Jun oncoprotein is very unstable in vivo. Using cell-free degradation assays, we show that ubiquitinylation, along with other types of tagging, is not an absolute prerequisite for ATP-dependent degradation of c-Jun by the 26 S proteasome. This indicates that a protein may bear intrinsic structural determinants allowing its selective recognition and breakdown by the 26 S proteasome. Moreover, taken together with observations by different groups, our data point to the notion of the existence of multiple degradation pathways operating on c-Jun.

PEST motifs are not required for rapid calpain-mediated proteolysis of c-fos protein.

Cytoplasmic degradation of c-fos protein is extremely rapid. Under certain conditions, it is a multi-step process initiated by calcium-dependent and ATP-independent proteases called calpains. PEST motifs are peptide regions rich in proline, glutamic acid/aspartic acid and serine/threonine residues, commonly assumed to constitute built-in signals for rapid recognition by intracellular proteases and particularly by calpains. Using a cell-free degradation assay and site-directed mutagenesis, we report here that the three PEST motifs of c-fos are not required for rapid cleavage by calpains. Testing the susceptibility of PEST motif-bearing and non-bearing transcription factors including GATA1, GATA3, Myo D, c-erbA, Tal-1 and Sry, demonstrates that PEST sequences are neither necessary nor sufficient for specifying degradation of other proteins by calpains. This conclusion is strengthened by the observation that certain proteins, reportedly known to be cleavable by calpains, are devoid of PEST motifs.

Complex mechanisms for c-fos and c-jun degradation.

c-fos and c-jun proto-oncogenes have originally been found in mutated forms in murine and avian oncogenic retroviruses. They both define multigenic families of transcription factors. Both c-jun and c-fos proteins are metabolically unstable. In vivo and in vitro work by various groups suggests that multiple proteolytic machineries, including the lysosomes, the proteasome and the ubiquitous calpains, may participate in the destruction of c-fos and c-jun. The relative contribution of each pathway is far from being known and it cannot be excluded that it varies according to the cell context and/or the physiological conditions. It has been demonstrated that, in certain occurrences, the degradation of both c-fos and c-jun by the proteasome in vivo involves the ubiquitin pathway. However, the possibility that proteasomal degradation can also occur in a manner independent of the E1 enzyme of the ubiquitin cycle remains an open issue.

Are there multiple proteolytic pathways contributing to c-Fos, c-Jun and p53 protein degradation in vivo?

The c-Fos and c-Jun oncoproteins and the p53 tumor suppressor protein are short-lived transcription factors. Several catabolic pathways contribute to their degradation in vivo. c-Fos and c-Jun are thus mostly degraded by the proteasome, but there is indirect evidence that, under certain experimental/physiological conditions, calpains participate in their destruction, at least to a limited extent. Lysosomes have also been reported to participate in the destruction of c-Fos. Along the same lines, p53 is mostly degraded following the ubiquitin/proteasome pathway and calpains also seem to participate in its degradation. Moreover, c-Fos, c-Jun and p53 turnovers are regulated upon activation of intracellular signalling cascades. All taken together, these observations underline the complexity of the mechanisms responsible for the selective destruction of proteins within cells.

The sensitivity of c-Jun and c-Fos proteins to calpains depends on conformational determinants of the monomers and not on formation of dimers.

Milli- and micro-calpains are ubiquitous cytoplasmic cysteine proteases activated by calcium. They display a relatively strict specificity for their substrates which they usually cleave at only a limited number of sites. Motifs responsible for recognition by calpains have not been characterized yet, and recently a role for PEST motifs in this process has been ruled out. c-Fos and c-Jun transcription factors are highly sensitive to calpains in vitro. They thus provide favourable protein contexts for studying the structural requirements for recognition and degradation by these proteases. Using in vitro degradation assays and site-directed mutagenesis, we report here that susceptibility to calpains is primarily determined by conformational determinants of the monomers and not by the quaternary structure of c-Fos and c-Jun proteins. The multiple cleavage sites borne by both proteins can be divided into at least two classes of sensitivity, the most sensitive ones being easily visualized in the presence of rate-limiting amounts of calpains. One site located at position 90-91 in c-Fos protein is extremely sensitive. However, efficient proteolysis did not have any strict dependence on the nature of the amino acids on either side of the scissile bond in the region extending from P2 to P'2. The structural integrity of the monomers is not crucial for recognition by calpains. Rather, sensitive sites can be recognized independently and their recognition is dependent on the local conformation of peptide regions that may span several tens of amino acids and maybe more in the case of the identified c-Fos hypersensitive site.