Project description:Holocarboxylase synthetase (HCS) catalyzes the binding of the vitamin biotin to histones H3 and H4, thereby creating rare histone biotinylation marks in the epigenome. These marks co-localize with K9-methylated histone H3 (H3K9me), an abundant gene repression mark. The abundance of H3K9me marks in transcriptionally competent loci decreases when HCS is knocked down and when cells are depleted of biotin. Here we tested the hypothesis that the creation of H3K9me marks is at least partially explained by physical interactions between HCS and histone-lysine N-methyltransferases. Using a novel in silico protocol, we predicted that HCS-interacting proteins contain a GGGG(K/R)G(I/M)R motif. This motif, with minor variations, is present in the histone-lysine N-methyltransferase EHMT1. Physical interactions between HCS and the N-terminal, ankyrin and SET domains in EHMT1 were confirmed using yeast-two-hybrid assays, limited proteolysis assays and co-immunoprecipitation. The interactions were stronger between HCS and the N-terminus in EHMT1 compared with the ankyrin and SET domains, consistent with the localization of the HCS-binding motif in the EHMT1 N-terminus. HCS has the catalytic activity to biotinylate K161 within the binding motif in EHMT1. Mutation of K161 weakened the physical interaction between EHMT1 and HCS, but it is unknown whether this effect was caused by loss of biotinylation or loss of the motif. Importantly, HCS knockdown decreased the abundance of H3K9me marks in repeats, suggesting that HCS plays a role in creating histone methylation marks in these loci. We conclude that physical interactions between HCS and EHMT1 mediate epigenomic synergies between biotinylation and methylation events.

Project description:HLCS (holocarboxylase synthetase) is a nuclear protein that catalyses the binding of biotin to distinct lysine residues in chromatin proteins. HLCS-dependent epigenetic marks are over-represented in repressed genomic loci, particularly in repeats. Evidence is mounting that HLCS is a member of a multi-protein gene repression complex, which determines its localization in chromatin. In the present study we tested the hypothesis that HLCS interacts physically with N-CoR (nuclear receptor co-repressor) and HDAC1 (histone deacetylase 1), thereby contributing toward the removal of H3K9ac (Lys?-acetylated histone H3) gene activation marks and the repression of repeats. Physical interactions between HLCS and N-CoR, HDAC1 and a novel splicing variant of HDAC1 were confirmed by co-immunoprecipitation, limited proteolysis and split luciferase complementation assays. When HLCS was overexpressed, the abundance of H3K9ac marks decreased by 50% and 68% in LTRs (long terminal repeats) 15 and 22 respectively in HEK (human embryonic kidney)-293 cells compared with the controls. This loss of H3K9ac marks was linked with an 83% decrease in mRNA coding for LTRs. Similar patterns were seen in pericentromeric alpha satellite repeats in chromosomes 1 and 4. We conclude that interactions of HLCS with N-CoR and HDACs contribute towards the transcriptional repression of repeats, presumably increasing genome stability.

Project description:In a recent mass spectrometry screen, we identified 108 new proteins that were modified endogenously by covalent binding of biotin; members of the heat shock superfamily of proteins, including heat shock protein 72 (HSP72), were overrepresented among the biotinylated proteins. Mammals respond to infections by secreting extracellular HSP72 (eHSP72), which elicits an immune response. Here, using mass spectrometry and site-directed mutagenesis, we identified five biotinylation sites in HSP72. We used coimmunoprecipitation, mass spectrometry, and limited proteolysis assays to demonstrate that HSP72 interacts physically with the protein biotin ligase holocarboxylase synthetase (HLCS), leading to biotinylation of residues K112, K128 K348, K361, K415, and, probably, additional lysines. Finally, we demonstrated that HLCS-dependent biotinylation of eHSP72 increases expression of the chemokine regulated on activation normal T-expressed and presumably secreted (RANTES) by human embryonic kidney (HEK-293) cells. In conclusion, we report a novel endogenous modification of HSP72 and demonstrated that binding of biotin to eHSP72 prepares cells for a strong immune response.

Project description:Post-translational modifications of histones play important roles in chromatin structure and genomic stability. Distinct lysine residues in histones are targets for covalent binding of biotin, catalyzed by holocarboxylase synthetase (HCS) and biotinidase (BTD). Histone biotinylation has been implicated in heterochromatin structures, DNA repair, and mitotic chromosome condensation. To test whether HCS and BTD deficiency alters histone biotinylation and to characterize phenotypes associated with HCS and BTD deficiency, HCS- and BTD-deficient flies were generated by RNA interference (RNAi). Expression of HCS and BTD decreased by 65-90% in RNAi-treated flies, as judged by mRNA abundance, BTD activity, and abundance of HCS protein. Decreased expression of HCS and BTD caused decreased biotinylation of K9 and K18 in histone H3. This was associated with altered expression of 201 genes in HCS-deficient flies. Lifespan of HCS- and BTD-deficient flies decreased by up to 32% compared to wild-type controls. Heat tolerance decreased by up to 55% in HCS-deficient flies compared to controls, as judged by survival times; effects of BTD deficiency were minor. Consistent with this observation, HCS deficiency was associated with altered expression of 285 heat-responsive genes. HCS and BTD deficiency did not affect cold tolerance, suggesting stress-specific effects of chromatin remodeling by histone biotinylation. To our knowledge, this is the first study to provide evidence that HCS-dependent histone biotinylation affects gene function and phenotype, suggesting that the complex phenotypes of HCS- and BTD-deficiency disorders may reflect chromatin structure changes.

Project description:Biotin holocarboxylase synthetase was partially purified from pea leaves by a sequence of ammonium sulphate fractionation and DEAE 52-cellulose chromatography. Enzyme activity was assayed using apo-(biotin carboxyl carrier protein) from an Escherichia coli bir A mutant affected in biotin holocarboxylase synthetase activity. Conditions for optimal catalytic activity and biochemical parameters of the plant enzyme were determined. This is the first direct evidence of the existence of biotin holocarboxylase synthetase activity in plants.

Project description:Holocarboxylase synthetase (HLCS) is the only protein biotin ligase in the human proteome. HLCS-dependent biotinylation of carboxylases plays crucial roles in macronutrient metabolism. HLCS appears to be an essential part of multiprotein complexes in the chromatin that cause gene repression and contribute toward genome stability. Consistent with these essential functions, HLCS knockdown causes strong phenotypes including shortened life span and low stress resistance in Drosophila melanogaster, and de-repression of long-terminal repeats in humans, other mammalian cell lines and Drosophila. Despite previous observations that the expression of HLCS depends on biotin status in rats and in human cell lines, little is known about the regulation of HLCS expression. The goal of this study was to identify promoters that regulate the expression of the human HLCS gene. Initially, the human HLCS locus was interrogated in silico using predictors of promoters including sequences of HLCS mRNA and expressed sequence tags, CpG islands, histone marks denoting transcriptionally poised chromatin, transcription factor binding sites and DNaseI hypersensitive regions. Our predictions revealed three putative HLCS promoters, denoted P1, P2 and P3. Promoters lacked a TATA box, which is typical for housekeeping genes. When the three promoters were cloned into a luciferase reporter plasmid, reporter gene activity was at least three times background noise in human breast, colon and kidney cell lines; activities consistently followed the pattern P1>>P3>P2. Promoter activity depended on the concentration of biotin in culture media, but the effect was moderate. We conclude that we have identified promoters in the human HLCS gene.

Project description:Holocarboxylase synthetase (HLCS) catalyzes the covalent binding of biotin to histones. Biotinylated histones are gene repression marks and are particularly enriched in long terminal repeats, telomeres, and other repeat regions. The effects of HLCS in gene regulation are mediated by its physical interactions with chromatin proteins such as histone H3, DNMT1, MeCP2, and EHMT-1. It appears that histone biotinylation depends on prior methylation of cytosines. De-repression of long terminal repeats in biotin- or HLCS-deficient cell cultures and organisms is associated with genome instability.

Project description:Holocarboxylase synthetase (HCS) catalyzes the binding of the vitamin biotin to carboxylases and histones. Carboxylases mediate essential steps in macronutrient metabolism. For example, propionyl-CoA carboxylase (PCC) catalyzes the carboxylation of propionyl-CoA in the metabolism of odd-chain fatty acids. HCS comprises four putative domains, i.e., the N-terminus, the biotin transfer/ATP-binding domain, a putative linker domain, and the C-terminus. Both N- and C-termini are essential for biotinylation of carboxylases by HCS, but the exact functions of these two domains in enzyme catalysis are unknown. Here we tested the hypothesis that N- and C-termini play roles in substrate recognition by HCS. Yeast-two-hybrid (Y2H) assays were used to study interactions between the four domains of human HCS with p67, a PCC-based polypeptide and HCS substrate. Both N- and C-termini interacted with p67 in Y2H assays, whereas the biotin transfer/ATP-binding and the linker domains did not interact with p67. The essentiality of N- and C-termini for interactions with carboxylases was confirmed in rescue experiments with mutant Saccharomyces cerevisiae, using constructs of truncated human HCS. Finally, a computational biology approach was used to model the 3D structure of human HCS and identify amino acid residues that interact with p67. In silico predictions were consistent with observations from Y2H assays and yeast rescue experiments, and suggested docking of p67 near Arg508 and Ser515 within the central domain of HCS.

Project description:We investigated in a patient with holocarboxylase synthetase deficiency, the relation between the biochemical and genetic factors of the mutant protein with the pharmacokinetic factors of successful biotin treatment. A girl exhibited abnormal skin at birth, and developed in the first days of life neonatal respiratory distress syndrome and metabolic abnormalities diagnostic of multiple carboxylase deficiency. Enzyme assays showed low carboxylase activities. Fibroblast analysis showed poor incorporation of biotin into the carboxylases, and low transfer of biotin by the holocarboxylase synthetase enzyme. Kinetic studies identified an increased Km but a preserved Vmax. Mutation analysis showed the child to be a compound heterozygote for a new nonsense mutation Q379X and for a novel missense mutation Y663H. This mutation affects a conserved amino acid, which is located the most 3' of all recorded missense mutations thus far described, and extends the region of functional biotin interaction. Treatment with biotin 100mg/day gradually improved the biochemical abnormalities in blood and in cerebrospinal fluid (CSF), corrected the carboxylase enzyme activities, and provided clinical stability and a normal neurodevelopmental outcome. Plasma concentrations of biotin were increased to more than 500 nM, thus exceeding the increased Km of the mutant enzyme. At these pharmacological concentrations, the CSF biotin concentration was half the concentration in blood. Measuring these pharmacokinetic variables can aid in optimizing treatment, as individual tailoring of dosing to the needs of the mutation may be required.

Project description:Previously, we discovered that holocarboxylase synthetase (HCS) is a chromatin-associated protein in Drosophila melanogaster and that HCS deficiency alters chromatin structure and gene expression patterns, leading to decreased heat tolerance. The effects of HCS deficiency were attributed to decreased biotinylation of histones. However, HCS is known to mediate biotinylation of carboxylases in cytoplasm and mitochondria in addition to mediating biotinylation of histones. A challenge posed by the genetic analysis of HCS is to distinguish between the effects of decreased biotinylation of carboxylases from the effects of decreased histone biotinylation in the gene expression patterns and phenotypes observed in HCS-deficient flies. Here, we tested whether 3-methylcrotonyl-CoA carboxylase (MCC) mutant flies exhibit gene expression patterns and heat susceptibility similar to that in HCS-deficient Drosophila. Biotin transporter [sodium-dependent multivitamin transporter (SMVT)] mutants were used to investigate effects of cellular biotin depletion on gene expression and heat susceptibility. Deficiencies of MCC and SMVT in mutant flies were confirmed by real-time PCR, streptavidin blotting of holocarboxylases, and analysis of MCC activities; expression of HCS and biotinylation of histones were not altered in MCC and SMVT mutants. Gene expression patterns in MCC and SMVT mutants were different from that seen with HCS-deficient flies, as judged by the abundance of mRNA coding for defective chorion 1, chitin-binding peritrophin-A, dopamine receptor 2, and yolk protein 2. MCC mutants exhibited increased resistance to heat stress compared with wild-type flies. We conclude that gene expression patterns and phenotypes in HCS-deficient flies in previous studies are caused by decreased biotinylation of histones rather than MCC.