A gene for ribosomal protein P0 that belongs to the family of ribosomal P proteins was isolated from a Neurospora crassa cDNA library, using polyclonal antibodies against recombinant P0 protein from Saccharomyces cerevisiae. This is the first gene for ribosomal P0 protein to be cloned from filamentous fungi. The derived P0 protein sequence has a strong homology to other eukaryotic P0 proteins; yet, there is a notable alteration in the conservative C-terminal region, placing this protein among the unique sequences from protozoan parasites.
Boar seminal vesicle protein tyrosine acid phosphatase (PTAP) and human prostatic acid phosphatase (PAP) show high affinity for protein phosphotyrosine residues. The physico-chemical and kinetic properties of the boar and human enzymes are different. The main objective of this study was to establish the nucleotide sequence of cDNA encoding boar PTAP and compare it with that of human PAP cDNA. Also, the amino-acid sequence of boar PTAP was compared with the sequence of human PAP. PTAP was isolated from boar seminal vesicle fluid and sequenced. cDNA to boar seminal vesicle RNA was synthesized, amplified by PCR, cloned in E. coli and sequenced. The obtained N-terminal amino-acid sequence of boar PTAP showed 92% identity with the N-terminal amino-acid sequence of human PAP. The determined sequence of a 354 bp nucleotide fragment (GenBank accession number: GQ184596) showed 90% identity with the corresponding sequence of human PAP. On the basis of this sequence a 118 amino acid fragment of boar PTAP was predicted. This fragment showed 89% identity with the corresponding fragment of human PAP and had a similar hydropathy profile. The compared sequences differ in terms of their isoelectric points and amino-acid composition. This may explain the differences in substrate specificity and inhibitor resistance of boar PTAP and human PAP.
Phosphorylated fructose-1,6-bisphosphatase (FBPase) was isolated from rabbit muscle in an SDS/PAGE homogeneous form. Its dephosphorylation with alkaline phosphatase revealed 2.8 moles of inorganic phosphate per mole of FBPase. The phosphorylated FBPase (P-FBPase) differs from the dephosphorylated enzyme in terms of its kinetic properties like Km and kcat, which are two times higher for the phosphorylated FBPase, and in the affinity for aldolase, which is three times lower for the dephosphorylated enzyme. ephosphorylated FBPase can be a substrate for protein kinase A and the amount of phosphate incorporated per FBPase monomer can reach 2-3 molecules. Since interaction of muscle aldolase with muscle FBPase results in desensitisation of the latter toward AMP inhibition (Rakus & Dzugaj, 2000, Biochem. Biophys. Res. Commun. 275, 611-616), phosphorylation may be considered as a way of muscle FBPase activity regulation.
Phosphorylation of acidic ribosomal proteins P1/P2-P0 is a common phenomenon in eukaryotic organisms. It was found previously that in Trichosporon cutaneum, unlike in other yeast species, in addition to the two acidic ribosomal proteins, two other proteins of 15 kDa and 19 kDa of the small ribosomal subunit were phosphorylated. Here we describe two protein kinases: CKI and CKII, which are engaged in the modification of T. cutaneum ribosomal proteins. The acidic ribosomal proteins and the protein of 19 kDa were modified by CKII associated with ribosomes, while the protein of 15 kDa was modified by CKI. Protein kinase CKI was purified from cell-free extract (CKIC) and from ribosomal fraction (CKIR). The molecular mass of CKIC was established at 33 kDa while that of CKIR at 35-37 kDa. A protein of 40 kDa copurified with CKIR but not CKIC. Heparin significantly increased 40 kDa protein phosphorylation level by CKIR. Microsequencing analysis revealed the presence of CKI recognition motifs in the N-terminal fragment of the 40 kDa protein.
Expression of the rat α2-macroglobulin (MG) gene undergoes dynamic changes throughout an individual's life and during the acute-phase (AP) response. Details of the participation of the STAT family of transcription factors in its control remain incompletely understood. Here we examined the involvement of STAT5b in MG gene expression during development and the AP response. Immuno-blot analysis revealed the highest nuclear level of STAT5b in the fetus and during postnatal development, whereas in the adult it decreased. Stimulation of MG expression during the AP response was accompanied by a decrease in STAT5b. Examination of STAT5b localization revealed that the relative concentrations of STAT5b were higher in the nuclear matrix than in the nuclear extract. Affinity chromatography with the extended promoter region of the MG gene (-825/+12), followed by immuno-blot analysis, revealed dynamic changes in STAT5b binding. The highest concentration of the promoter-binding form of STAT5b was observed in the fetus. As postnatal development progressed, the level of promoter-bound STAT5b decreased and in the adult liver it was the lowest. Stimulation of MG gene expression during the AP response in both the fetus and adult was accompanied by significantly decreased STAT5b binding to the MG promoter. The AP response was accompanied by lower levels of STAT5b serine and tyrosine phosphorylation in both fetus and adult. In the nuclear matrix derived from adult tissues, tyrosine phosphorylated species were completely absent. We conclude that developmental-stage differences in the mechanisms that determine STAT5b nuclear localization contribute to its activity in vivo.
In this minireview the main mechanism of control of mammalian pyruvate dehydrogenase complex (PDHC) activity by phosphorylation-dephosphorylation is presented in the first place. The information recently obtained in several laboratories includes new data about isoforms of the PDH converting enzymes (kinase and phosphatase) and their action in view of short-term regulation of PDHC. Moreover, interesting influence of exogenous thiamine diphosphate (TDP) and some divalent cations, especially Mn2+, on the kinetic parameters of PDHC saturated with endogenous tightly bound TDP, is discussed. This influence causes a shortening of the lag-phase of the catalyzed reaction and a strong decrease of the Km value of PDHC mainly for pyruvate. There are weighty arguments that the effects have an allosteric nature. Thus, besides reversible phosphorylation, also direct manifold increase of mammalian PDHC affinity for the substrate by cofactors seems an important aspect of its regulation.
Reversible phosphorylation is the most widespread posttranslational protein modification, playing regulatory role in almost every aspect of cell life. The majority of protein phosphorylation research has been focused on serine, threonine and tyrosine that form acid-stable phosphomonoesters. However, protein histidine, arginine and lysine residues also may undergo phosphorylation to yield acid-labile phosphoramidates, most often remaining undetected in conventional studies of protein phosphorylation. It has become increasingly evident that acid-labile protein phosphorylations play important roles in signal transduction and other regulatory processes. Beside acting as high-energy intermediates in the transfer of the phosphoryl group from donor to acceptor molecules, phosphohistidines have been found so far in histone H4, heterotrimeric G proteins, ion channel KCa3.1, annexin 1, P-selectin and myelin basic protein, as well as in recombinant thymidylate synthase expressed in bacterial cells. Phosphoarginines occur in histone H3, myelin basic protein and capsidic protein VP12 of granulosis virus, whereas phospholysine in histone H1. This overview of the current knowledge on phosphorylation of protein basic amino-acid residues takes into consideration its proved or possible roles in cell functioning. Specific requirements of studies on acid-labile protein phosphorylation are also indicated.
Epigenetics analyses inherited characteristics not directly connected to the DNA nucleotide sequence. It investigates the relationships between biochemical modifications and the expression of selected genes. Initially, it was thought that gene expression depends on information encoded in the DNA sequence. However, it was discovered that the activity of many enzymes like methylases, demethylases, acetylases, deacetylases is necessary to regulate this process and its dysregulations may lead to e.g. cancer initiation and progression. Epigenetics has an impact on neoplastic transformation by reducing the global level of DNA methylation and increasing the methylation level within tumour suppressor gene promoters, which significantly impairs the repression of carcinogenesis. Additionally, modifications of histone proteins, based on disorders of acetylation-deacetylation and methylation-demethylation processes, may lead to overexpression of genes involved in cancer development. Numerous examples have been described, among others breast, prostate and colon cancers, depending on the modification of histone amino tails, primarily of histone H3. For such reasons, the possibility of using many therapies which can reverse the negative effect of these modifications by e.g. DNA demethylation (DNA demethylating drugs) or re-acetylation of histone lysine resides (histone deacetylase inhibitors) is examined. In the near future, epigenetics probably will allow the effective treatment of some cancer diseases, although further research on the impact of enzymatic modifications on the development of carcinogenesis is still needed.
PL
Epigenetyka zajmuje się badaniem cech dziedzicznych, które nie zależą bezpośrednio od sekwencji nukleotydowej w DNA, ale są rezultatem modyfikacji biochemicznych na ekspresję wybranych genów. Początkowo uważano, że ekspresja genów zależy tylko od informacji zapisanej zawartej w sekwencji DNA, z czasem okazało się, że liczne modyfikacje będące rezultatem działania różnych grup enzymów, w tym metylaz, demetylaz, acetylaz czy deacetylaz, wpływają na regulację tego procesu, a zaburzenia regulacji aktywności tych enzymów mogą prowadzić do wystąpienia i rozwoju m.in. nowotworów. Epigenetyczny aspekt rozwoju transformacji nowotworowej wskazuje na obniżenie globalnego poziomu metylacji DNA oraz podwyższenie poziomu metylacji w obrębie promotorów genów supresorowych, co znacząco upośledza represję nowotworzenia. Dodatkowo, modyfikacje białek histonowych, opierające się na dysregulacji procesów acetylacji–deacetylacji i metylacji – demetylacji, prowadzą do nadekspresji genów zaangażowanych w rozwój kancerogenezy. Opisane zostały liczne przykłady zależności wystąpienia nowotworów, m.in. raka sutka, stercza czy okrężnicy od wystąpienia danej modyfikacji reszt aminokwasowych białek histonowych, w tym głównie histonu H3. Z takich też przyczyn podejmowane są próby zastosowania terapii odwracających negatywny skutek wybranych modyfikacji, np. poprzez demetylację DNA (leki demetylujące DNA) czy reacetylację reszt lizynowych histonów (inhibitory decetylaz histonów). W niedalekiej przyszłości epigenetyka najprawdopodobniej u możliwi skuteczne leczenie części chorób nowotworowych, aczkolwiek konieczne są dalsze badania wpływu modyfikacji enzymatycznych na mechanizm rozwoju kancerogenezy.
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