HDAC6, at the crossroads between cytoskeleton and cell signaling by acetylation and ubiquitination.

Histone deacetylase 6 (HDAC6) is a unique enzyme with specific structural and functional features. It is actively or stably maintained in the cytoplasm and is the only member, within the histone deacetylase family, that harbors a full duplication of its deacetylase homology region followed by a specific ubiquitin-binding domain at the C-terminus end. Accordingly, this deacetylase functions at the heart of a cellular regulatory mechanism capable of coordinating various cellular functions largely relying on the microtubule network. Moreover, HDAC6 action as a regulator of the HSP90 chaperone activity adds to the multifunctionality of the protein, and allows us to propose a critical role for HDAC6 in mediating and coordinating various cellular events in response to different stressful stimuli.

A new splicing acceptor site and poly(A)+ sequence signal within DQA1*0401 and DQA1*0501 mRNA 3'UTR contribute to increase the extraordinary diversity of mRNA isoforms.

In this paper, we have analysed the diversity of mRNA species generated by DQA1*0501 and DQA1*0401 alleles in homozygous B-lymphoblastoid cell lines. As we previously reported, six mRNA isoforms that differ in the 3'UTR have been identified in these cells. This diversity of mRNA species results both from the alternative use of two acceptor spliced sites and the differential selection of two poly(A)+ sequence signals by the processing machinery. In this report we describe a new acceptor sequence signal that allows generation of a new alternative spliced mRNA species. This acceptor sequence signal was also present in all of the seven DQA1 homozygous cell lines analysed. In addition, we have identified a previously undetected, non-conventional but functional, poly(A)+ sequence signal that lacks an identifiable AATAAA hexamer, one of the most important element of the core. This sequence signal allows the generation of two additional mRNA isoforms both in DQA1*0501 and DQA1*0401 homozygous cell lines but not in the others. We show that DQA1*0501 and DQA1*0401 primary transcripts can be processed into nine mRNA isoforms that differ in the 3'UTR. Finally, we summarized all the DQA1 mRNA species deriving from DQA1*0101, DQA1*0102, DQA1*0103, DQA1*0201, DQA1*0301, DQA1*0401 and DQA1*0501 alleles and shown in B-lymphoblastoid cell lines.

HLA DQA1 genes generate multiple transcripts by alternative splicing and polyadenylation of the 3' untranslated region.

Regulation of the human leucocyte antigen (HLA) class II genes expression is an important field in immunology, because these molecules play a crucial role in the function of the immune system. HLA DQ genes expression is a complex phenomenon regulated at both transcriptional and post-transcriptional levels. In this study, we have investigated the post-transcriptional mechanisms accounting for alleles-dependent length polymorphism of DQA1 mRNA. We have first sequenced the genomic DNA encoding the 3' untranslated region (UTR) of DQA1 *0101, *0102, *0103, *0201, *0301, *0401, and *0501 alleles. We have identified two competing splicing sites: a unique splicing donor site AG/GTA located 20 nucleotides downstream from the stop codon associated to two spliced acceptor sequences, approximately 165 and approximately 370 nucleotides downstream. In addition, three polyadenylation signals have been identified, respectively, at approximately 475, approximately 795, and approximately 855 nucleotides downstream from the stop codon. Subsequently, we have analyzed mRNAs derived from DQA1 alleles in homozygous B lymphoblastoid cell lines by reverse transcriptase-polymerase chain reaction. We show that allele-dependent length polymorphism of DQA1 mRNA-3' UTR results from a combination of differential splicing and alternative polyadenylations. Four mRNA isoforms (two spliced variant cleaved at two distinct polyadenylation sites) were detected in DQA1 *0101, *0102, and *0103 homozygous cell lines, and six mRNA species (three spliced variant cleaved at two polyadenylation-sequence signal) were generated by the other four alleles. Possible advantages for cells to generate multiple transcripts previously undetected are discussed.

Comparison of TAP2 frequencies in type 1 diabetes patients and healthy controls from three ethnic groups indicates an African origin for the TAP2 G allele.

In order to determine the ethnic origin of the transporter associated with antigen processing 2 (TAP2) G allele, initially discovered by us in a group of type 1 diabetes (insulin-dependent diabetes mellitus) patients living on Reunion Island, HLA TAP2 typing was performed using the polymerase chain reaction-amplification refractory mutation system (PCR-ARMS) method in type 1 diabetes patients and unrelated healthy controls of three different ethnic groups (Caucasians, Indians and black Africans from Senegal and Mauritius). The comparison of TAP2 allele frequencies in controls showed significant racial (ethnic) differences. The TAP2*0101 and TAP2 C alleles were increased, respectively, in the Caucasian (50% in Caucasians vs. 40% in other groups) and Senegalese (27% in Senegalese vs. 10% in other groups) populations. In comparison with Caucasians, the TAP2*0201 variant was significantly increased in the Indian population and decreased in the Senegalese black population. In addition, the TAP2 G allele was observed in the two African populations studied but not in the Caucasian or Indian population. This observation is consistent with the view that this allele is restricted to populations of African origin. In addition, we have determined the large extended haplotype DQA1-DQB1-DRB1 associated with TAP2 G. We found that this allele is preferentially associated with the large conserved haplotype HLA DQA1*0501-DQB1*0201-DRB1*0301.

In vivo analysis of HLA-DQ gene expression in heterozygous cell lines.

Regulation of HLA-DQ gene transcription is a complex phenomenon because the allelic polymorphism associated with these genes and their promoters is a putative source of differential allele expression. Both transcriptional and post-transcriptional regulation could account for the density of the molecules expressed at the cell surface and then for the specificity of the immune response. Different methods have been developed to evaluate the functional consequences of this polymorphism, but at present no universal method allows measurement of either the steady-state level or the half-life time of mRNA species of both DQA1 and DQB1 polymorphic genes in heterozygous cell lines. Here, we propose a potent method, based on relative quantification of reverse transcriptase-polymerase chain reaction products, which analyzes the differential expression of all DQA1 or DQB1 allele combinations. This method is used to analyze the differential expression of HLA-DQB1*020110402 alleles in the human heterozygous lymphoblastoid B-cell line. Nucleotidic sequences of the proximal upstream regulatory region of these alleles exhibit significant differences. We show that the DQB1*0402 promoter is able to mediate a transcription strength twice as efficiently as *0201. In addition, the *0402 mRNA steady-state level is also governed by a remarkable post-transcriptional regulation. Indeed, an important part (20%) of the *0402 primary transcript is derived by alternative splicing in a short mRNA translated into a nonfunctional protein. Despite their variable sequence and length, no difference in the half-life of DQB1*0201 and both DQB*0402 mRNAs was observed in B-lymphoblastoid cells. The implications of these findings are discussed.

S-phase-dependent action of cycloheximide in relieving chromatin-mediated general transcriptional repression.

Chromatin plays a major role in the tight regulation of gene expression and in constraining inappropriate gene activity. Replication-coupled chromatin assembly ensures maintenance of these functions of chromatin during S phase of the cell cycle. Thus treatment of cells with an inhibitor of translation, such as cycloheximide (CX), would be expected to have a dramatic effect on chromatin structure and function, essentially in S phase of the cell cycle, due to uncoupled DNA replication and chromatin assembly. In this work, we confirm this hypothesis and show that CX can induce a dramatic S-phase-dependent alteration in chromatin structure that is associated with general RNA polymerase II-dependent transcriptional activation. Using two specific RNA polymerase II-transcribed genes, we confirm the above conclusion and show that CX-mediated transcriptional activation is enhanced during the DNA replication phase of the cell cycle. Moreover, we show co-operation between an inhibitor of histone deacetylase and CX in inducing gene expression, which is again S-phase-dependent. The modest effect of CX in inducing the activity of a transiently transfected promoter shows that the presence of the promoter in an endogenous chromatin context is necessary in order to observe transcriptional activation. We therefore suggest that the uncoupled DNA replication and histone synthesis that occur after CX treatment induces a general modification of chromatin structure, and propose that this general disorganization of chromatin structure is responsible for a widespread activation of RNA polymerase II-mediated gene transcription.

Informations on the active site of palmito polyphenol oxidase.

pH studies of palmito polyphenol oxidase are carried out with either 4-methylcatechol or pyrogallol as substrates. The pH profile is independent of the nature of the substrates tested. The symmetrical behaviour and the very slight differences between the values obtained suggest the existence of only one site on the molecule for o-diphenol substrates.

Recovery of RNA from flow-sorted fixed cells.

We describe a method for the preparation of RNA from ethanol-fixed cells, allowing analysis of the RNA from cells "frozen" in a given physiological state. This technique may have important applications in experiments which require prolonged cell manipulations before RNA preparation, such as investigations of cell-cycle-regulated gene expression, which require the preparation of cells for cell-cycle flow analysis, and even for long-term cell sorting. It eliminates all the inconveniences associated with the use of fresh cells, and allows cell-cycle biologists to couple flow cytometry methodology with the advancing techniques of molecular biology.

Sliding of STOP proteins on microtubules: a model system for diffusion-dependent microtubule motility.

STOP proteins, of 145 kD, act substoichiometrically to block end-wise disassembly of microtubules. STOPs bind to microtubules either during microtubule assembly or when added at steady state, and when binding to the polymers is apparently irreversible. They are not measurably lost from polymers under competition conditions, and there is no measurable exchange between polymers. Nonetheless, STOP proteins exhibit an extraordinary behavior: they "slide" laterally on the surface of the microtubule. Displacement is assayed by forming hybrid microtubules in which cold stable or cold labile region subunits are labeled. Displacement of STOPs on the polymer with time will cause labeled subunits of cold-stable regions to become increasingly cold labile in a manner reciprocal to cold stabilization of previously cold-labile subunits. Because equilibrium exchange of STOP proteins onto and off the polymers can be ruled out, the displacement of STOPs relative to subunits can only be explained by lateral diffusion or "sliding." Axonal transport and mitotic mechanisms were discussed as implications of such a lateral translocation mechanism for microtubule-dependent motility.

Generation of microtubule stability subclasses by microtubule-associated proteins: implications for the microtubule "dynamic instability" model.

We have developed a method to distinguish microtubule associated protein (MAP)-containing regions from MAP-free regions within a microtubule, or within microtubule sub-populations. In this method, we measure the MAP-dependent stabilization of microtubule regions to dilution-induced disassembly of the polymer. The appropriate microtubule regions are identified by assembly in the presence of [3H]GTP, and assayed by filter trapping and quantitation of microtubule regions that contain label. We find that MAPs bind very rapidly to polymer binding sites and that they do not exchange from these sites measurably once bound. Also, very low concentrations of MAPs yield measurable stabilization of local microtubule regions. Unlike the stable tubule only polypeptide (STOP) proteins, MAPs do not exhibit any sliding behavior under our assay conditions. These results predict the presence of different stability subclasses of microtubules when MAPs are present in less than saturating amounts. The data can readily account for the observed "dynamic instability" of microtubules through unequal MAP distributions. Further, we report that MAP dependent stabilization is quantitatively reversed by MAP phosphorylation, but that calmodulin, in large excess, has no specific influence on MAP protein activity when MAPs are on microtubules.

Sliding of STOP proteins on microtubules.

Microtubules are stabilized against cold temperature disassembly by 145-kilodalton proteins [stable tubule only polypeptides (STOPs)] that block the end-wise dissociation of subunits from the polymers. We describe here several kinetic parameters of the interaction of STOPs with microtubules. STOPs will bind to microtubules either during assembly of the polymer or at steady state. The addition appears random on the polymers and does not require the mediation of tubulin subunits. Tubulin subunits compete with microtubules for STOP binding, but binding to the polymers is apparently irreversible. We demonstrate that STOPs do not exchange measurably between polymers at steady state. Nonetheless, a displacement of STOPs within a single polymer is readily demonstrable. We have determined that the displacement is apparently due to a surface translocation, or "sliding", of STOPs on microtubules.