Overexpression of the heat-shock protein 70 is associated to imatinib resistance in chronic myeloid leukemia.

Imatinib is an effective therapy for chronic myeloid leukemia (CML), a myeloproliferative disorder characterized by the expression of the recombinant oncoprotein Bcr-Abl. In this investigation, we studied an imatinib-resistant cell line (K562-r) generated from the K562 cell line in which none of the previously described mechanisms of resistance had been detected. A threefold increase in the expression of the heat-shock protein 70 (Hsp70) was detected in these cells. This increase was not associated to heat-shock transcription factor-1 (HSF-1) overexpression or activation. RNA silencing of Hsp70 decreased dramatically its expression (90%), and was accompanied by a 34% reduction in cell viability. Overexpression of Hsp70 in the imatinib-sensitive K562 line induced resistance to imatinib as detected by a large reduction in cell death in the presence of 1 muM of imatinib. Hsp70 level was also increased in blast cells of CML patients resistant to imatinib, whereas the level remained low in responding patients. Taken together, the results demonstrate that overexpression of Hsp70 can lead to both in vitro and in vivo resistance to imatinib in CML cells. Moreover, the overexpression of Hsp70 detected in imatinib-resistant CML patients supports this mechanism and identifies potentially a marker and a therapeutic target of CML evolution.

MOD-D, a Galpha subunit of the fungus Podospora anserina, is involved in both regulation of development and vegetative incompatibility.

Cell death via vegetative incompatibility is widespread in fungi but molecular mechanism and biological function of the process are poorly understood. One way to investigate this phenomenon was to study genes named mod that modified incompatibility reaction. In this study, we cloned the mod-D gene that encodes a Galpha protein. The mod-D mutant strains present developmental defects. Previously, we showed that the mod-E gene encodes an HSP90. The mod-E1 mutation suppresses both vegetative incompatibility and developmental defects due to the mod-D mutation. Moreover, we isolated the PaAC gene, which encodes an adenylate cyclase, as a partial suppressor of the mod-D1 mutation. Our previous results showed that the molecular mechanisms involved in vegetative incompatibility and developmental pathways are connected, suggesting that vegetative incompatibility may result from disorders in some developmental steps. Our new result corroborates the involvement of mod genes in signal transduction pathways. As expected, we showed that an increase in the cAMP level is able to suppress the defects in vegetative growth due to the mod-D1 mutation. However, cAMP increase has no influence on the suppressor effect of the mod-D1 mutation on vegetative incompatibility, suggesting that this suppressor effect is independent of the cAMP pathway.

Reactivity in vegetative incompatibility of the HET-E protein of the fungus Podospora anserina is dependent on GTP-binding activity and a WD40 repeated domain.

The het-e gene of the filamentous fungus Podospora anserina is involved in vegetative incompatibility. Co-expression of antagonistic alleles of the unlinked loci het-e and het-c triggers a cell death reaction that prevents the formation of viable heterokaryons between strains that contain incompatible combinations of het-c and het-e alleles. The het-elA gene encodes a polypeptide that contains a putative GTP-binding site and WD40 repeats. The role of these two domains in the reactivity of the HET-E protein in incompatibility was analyzed. An in vitro assay confirmed that the first domain is functional and can bind GTP and not ATP, suggesting that GTP-binding is essential for triggering the incompatibility reaction. The relationship between the number of WD40 repeats and the reactivity of the protein in incompatibility was investigated by estimating this number in different wild-type and mutant het-e alleles. It was deduced that reactive alleles contain a minimal number of ten WD40 repeats. These results demonstrate that the reactivity of the HET-E protein depends on two functional elements, a GTP-binding domain and several WD40 repeats. These motifs are present in separate polypeptides in trimeric G proteins, suggesting that HET-E polypeptides are also involved in signal transduction. Disruption of the het-e locus does not impair the phenotype of strains but DNA hybridization analyses revealed that het-e may belong to a multigenic family.

An additional copy of the adenylate cyclase-encoding gene relieves developmental defects produced by a mutation in a vegetative incompatibility-controlling gene in Podospora anserina.

To identify cellular functions involved in vegetative incompatibility in filamentous fungi, we have initiated the cloning of Podospora anserina (Pa) mod genes. These genes interfere with the lethal reaction triggered by interaction between incompatible het genes. A gene (Pa AC) has been cloned by complementation of developmental defects caused by a mutation in the mod-D gene. This gene encodes a protein of 2145 amino acids (aa)that exhibits strong similarities with many adenylate cyclases (AC). About 65% aa identity has been found between the sequence of the polypeptide encoded by this Pa AC gene and the AC of Neurospora crassa. The organization of peptidic domains in the polypeptide encoded by Pa AC is closely related to that of Saccharomyces cerevisiae CYR1. Restriction-fragment-length polymorphism (RFLP) and genetic analysis have shown that Pa AC and mod-D are distinct genes.

A gene responsible for vegetative incompatibility in the fungus Podospora anserina encodes a protein with a GTP-binding motif and G beta homologous domain.

The het-e-1 gene of the fungus Podospora anserina is responsible for vegetative incompatibility through specific interactions with different alleles of the unlinked gene, het-c. Coexpression of two incompatible genes triggers a cell death reaction that prevents heterokaryon formation. The het-e1 allele has been cloned to get information on the function of the locus. It encodes a putative 1356-amino-acid polypeptide that displays two sequence motifs that have not yet been reported to be present on a single polypeptide. They are a GTP-binding domain and a repeated region that shares similarity with that of the beta-transducin. Contrary to other members of the beta-transducin family, sequence conservation between the repeated units is very strong and the number of repeats is different in wild-type het-e alleles.

Inactivation of the Podospora anserina vegetative incompatibility locus het-c, whose product resembles a glycolipid transfer protein, drastically impairs ascospore production.

The het-c locus contains different alleles that elicit nonallelic vegetative incompatibility through specific interactions with alleles of the unlinked loci het-e and het-d. The het-c2 allele has been cloned. It encodes a 208-amino acid polypeptide that is similar to a glycolipid transfer protein purified from pig brain. Disruption of this gene drastically impairs ascospore production in homozygous crosses, and some mutants exhibit abnormal branching of apical hyphae. The protein encoded by het-c2 is essential in the biology of the fungus and may be involved in cell-wall biosynthesis.

Two allelic genes responsible for vegetative incompatibility in the fungus Podospora anserina are not essential for cell viability.

Vegetative incompatibility is a lethal reaction that destroys the heterokaryotic cells formed by the fusion of hyphae of non-isogenic strains in many fungi. That incompatibility is genetically determined is well known but the function of the genes triggering this rapid cell death is not. The two allelic incompatibility genes, s and S, of the fungus Podospora anserina were characterized. Both encode 30 kDa polypeptides, which differ by 14 amino acids between the two genes. These two proteins are responsible for the incompatibility reaction that results when cells containing s and S genes fuse. Inactivation of the s or S gene by disruption suppresses incompatibility but does not affect the growth or the sexual cycle of the mutant strains. This suggests that these incompatibility genes have no essential function in the life cycle of the fungus.