X-ray characterization of PaPheOH, a bacterial phenylalanine hydroxylase

Ekström, Fredrik

January 2003

Many human diseases are associated with the malfunction of enzymes in the aromatic amino acid hydroxylase family, e.g. phenylketonuria (PKU), hyperphenylalaninemia (HPA), schizophrenia and Parkinson's disease. The family of aromatic aminoacid hydroxylases comprises the enzymes phenylalanine hydroxylase (PheOH), tyrosine hydroxylase (TyrOH) and tryptophane hydroxylase (TrpOH). These enzymes require the cofactor (6R)-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4) and atomic oxygen. In eukaryotes, the aromatic amino acid hydroxylases share the same organization with a N-terminal regulatory domain, a central catalytic domain and a C-terminal tetramerization domain. Aromatic amino acid hydroxylases that correspond to the core catalytic domain of the eukaryotic enzymes are found in bacteria. The main focus of this thesis is the structural characterization of a phenylalanine hydroxylase from the bacterium Pseudomonas aeruginosa (PaPheOH). To initiate the structural characterization, the active site environment was investigated with X-ray absorption spectroscopy (XAS). The experimental data support a model where the active site iron is coordinated by four oxygen atoms and two nitrogen atoms. We suggest that two water molecules, His121, His126 and Glu166 coordinates the active site iron. In this model, Glu166 provides two of the oxygen atoms in a bidentate binding geometry. EXAFS and XANES studies indicate that structural rearrangements are induced in the second and third coordination shells in samples of PaPheOH with BH4 and/or L-Phe. The 1.6 Å X-ray structure of PaPheOH shows a catalytic core that is composed of helices and strands in a bowl-like arrangement. The iron is octahedrally coordinated, by two water molecules and the evolutionary conserved His121, His126 and Glu166 that coordinates the iron with bidentate geometry. The pterin binding loop of PaPheOH (residue 81-86) adopts a conformation that is displaced by 5-6 Å from the expected pterin binding site. Consistent with the unfavourable position of the pterin binding loop is the observation that PaPheOH has a low specific activity compared to the enzymes from human and Chromobacterium violaceum. The second part of this thesis focus on the crystallization and structure determination of the actin binding domain of a-actinin (ABD). a-Actinin is located in the Z-disc of skeletal muscle were it crosslinks actin filaments to the filamentous protein titin. The ABD domain of a-actinin crystallizes in space group P21 with four molecules in the asymmetric unit. The structure of the ABD domain has been solved to a d-spacing of 2.0 Å. The two CH-domains of ABD is composed of 5 a-helices each. The a-helices fold into a closed compact conformation with extensive intramolecular contacts between the two domains.

Biochemistry

PaPheOH

PheOH

PAH

phhA

phenylalanine hydroxylase

protein crystallography

a-actinin

microcrystal

ABD

CH-domain

Biokemi

Biochemistry

Biokemi

α-aktinino-3 deficito įtaka greitumo, raumenų galingumo ir jėgos kaitai, lavinant greitumą / α-actinin-3 deficiency and maximum running speed workouts influence to running speed, power and strength variation

Baltušnikas, Juozas

26 May 2010

Greitumas – vienas iš svarbiausių judamųjų gebėjimų. Jis įvairiose sporto šakose pasireiškia skirtingomis formomis. Greitumo pratybos, tai tokios pratybos, kurios nemažina maksimalaus raumens susitraukimo ir atsipalaidavimo greičio, o jį padidina. Yra žinoma, kad jėgos pratybos yra kenksmingos greitumui. Mūsų nuomone, didžiausia problema sporto moksle - kaip padidinti jėgą nesumažinant raumens susitraukimo ir atsipalaidavimo greičio. Taip pat labai aktualu sužinoti, kaip skirtingų genų variantų žmonės geba didinti greitumą ir jo pasireiškimo formas. Šiuo metu pasirodė daug straipsnių apie ACTN3 R577X polimorfizmą. Yra žinoma, kad α-aktinino-3 baltymo nėra pas 16 % pasaulio žmonių. Įdomu tai, kad mutavusio (X) alelio ir ypač pilno α-aktinino-3 (alelis XX) deficito dažnis yra ženkliai mažesnis tarp sprinto ir galingumo atletus. Todėl mes savo tyrime analizavome greitumo pratybų įtaką didesnio jėgos indėlio reikalaujantiems pratimams ir gautus rezultatus lyginome tarp skirtingų RR ir XX genotipų. Tyrimo tikslas – ištirti maksimalaus greitumo padidėjimo įtaką didesnio jėgos indėlio reikalaujantiems judamiesiems gebėjimams priklausomai nuo RR (gaminasi α-aktininas-3) ir XX (nesigamina α-aktininas-3) genotipo. Tyrimo objektas – greitumo pokytis ir to pokyčio įtaka didesnės jėgos reikalaujantiems judamiesiems gebėjimams RR ir XX genotipo grupėse. Tyrimo uždaviniai: 1. Nustatyti ir įvertinti, kaip po 10 maksimalaus greitumo lavinimo pratybų kito RR ir XX grupių greitumo judamasis... [toliau žr. visą tekstą] / Running speed is one of the most important physical properties. It has various forms. Speed training does not decrease muscle contraction and relaxation speed. It is well known, that strength training decrease running speed results. That’s why we think that maybe the most important problem in sport science is how to increase strength without maximum muscle contraction and relaxation speed decrease. Also it is important to know how people with different genotypes can increase running speed. There are only few articles about ACTN3 R577X polymorphism. A common nonsense mutation (R577X) in the ACTN3, resulting in a premature stop codon and lack of detectable protein in homozygous individuals for the ACTN3 null allele (XX genotype), has been demonstrated in the general human population with 16 % prevalence in Caucasians. Sprint athletes have lower 577XX genotype frequency endurance athletes. That’s why we analyze running speed workouts influence to more strength required physical properties between RR and XX groups. The aim of the study - to investigate running speed increment influence to more strength required physical properties and compare results between RR (with α-actinin-3) and XX (without α-actinin-3) groups. The object of the study - running speed change and this change influence to more strength required physical properties between RR (with α-actinin-3) and XX (without α-actinin-3) groups. Study tasks: 1. To investigate how after maximum speed workouts vary running speed... [to full text]

Biology

Greitumo prieaugis

α-aktinino-3 R557X polimorfizmas

Judamieji gebėjimai

Increasing running speed

α-actinin-3 deficiency

Running speed influence

ACTN3

Genetické faktory ovlivňující průběh vybraných forem nefrotického syndromu / Genetic factors affecting course of selected forms of nephrotic syndrome

Šafaříková, Markéta

January 2011

Nephrotic syndrome (NS) is characterized by proteinuria, hypalbuminemia and edemas. It occurs during first and second glomerulopathies. This disease can be divided into two groups: primary (idiopathic) and secondary. The heredity of the familial nephrotic syndrome is autosomal dominant and autosomal recessive. There are four most important genes that condition the formation of hereditary nephrotic syndrome in adult patienst. These genes are ACTN4, CD2AP, NPHS2 and TRPC6. The gene ACTN4, which encodes protein α-actinin 4, is responsible for the autosomal dominant form of focal segmental glomerulosclerosis (FSGS). FSGS is included in first glomerulopathies. α-Actinin 4 was also researched for some types of carcinomas. There was performed the mutational analysis of the gene ACTN4 on the set of 48 patients with nephrotic syndrome in this diploma thesis. High resolution melting (HRM) analysis and sequencing selected samples were used during this mutation detection. During this process many published and unpublished SNPs and one unpublished candidate mutation that could have causal associations with FSGS were found.

Makrophageninfiltration, Hypoxie und Stickstoffmonoxidsynthasen im humanen Nierenzellkarzinom / Makrophageninfiltration, Hypoxie und Stickstoffmonoxidsynthasen im humanen Nierenzellkarzinom

Hümmer, Tanja Melanie

05 December 2011

No description available.

610 Medizin, Gesundheit

Medicine

Nierenzellkarzinom

Tumorassoziierte Makrophagen

Hypoxie

Stickstoffmonoxidsynthasen

Nitrotyrosin

alphα-actinin-4

iNOS

eNOS

Nitrit

CD68

Gefäßdichte

Nekrose

Immunhistochemie

renal cell carcinoma

tumor-associated macrophages

hypoxia

nitric oxide synthase

nitrotyrosine

alphα-actinin-4

iNOS

eNOS

nitrite

CD68

vascular density

necrosis

immunohistochemistry

44 Medizin

Medizin