Gene association of a-B-crystallin with R577X polymorphism for ACTN3 and nociception in subjects with TMD-related myalgia

Konovalenko, Zhanna

January 2016

Masseter muscle is one of the major muscles of mastication, and is comprised of actin and myosin myofibrils organized into sarcomeric contractile units. Structurally, sarcomeres are repeating portions of myofibrils between neighboring Z-lines (a.k.a. Z-disc, Z-band). The Z-line or Z-disc is composed of non-contractile proteins that provide mechanical stability to the sarcomere. One of the proteins of Z-disc is alpha-B-crystallin, a protein product of the gene CRYAB. Together with several other proteins of the Z-disc, CRYAB gene has been found to be up-regulated in Actn3 knock-out mice. In addition, CRYAB is suspected to be a pain mediator gene, having similar structure and function to CRYAA (alpha,A-crystallin) identified as one of the candidate genes from the Pain Research Panel, previously investigated in the Orofacial Pain: Prospective Evaluation and Risk Assessment (OPPERA) Study. Finally, in a microarray of global gene expression CRYAB was increased in subjects with facial asymmetry. We have examined CRYAB expression in masseter muscle of 64 orthognathic surgery patients to determine associations with skeletal malocclusions. Salivary DNA was genotyped for a single nucleotide polymorphism (SNP) for ACTN3 (rs1815739) and masseter muscle RNA isolated from an orthognathic surgery patient population. These genotyping and expression data have been used to identify differences in CRYAB expression in sub-groups of our patient population with Class II and III, normal, open and deep bite malocclusions who are null for ACTN3. In addition, we evaluated expression levels of CRYAB in patients with TMD-related myalgia. We found that relative quantities of CRYAB expression differed very significantly between sexes (p=0.005). ANOVA comparison between all subjects with and without TMD-myalgia indicated that males with TMD-myalgia had significantly greater (p<0.02) expression than other groups. An unpaired t-test showed that with TMD-related myalgia, CRYAB expression was significantly higher (p=0.03) in males than in females. ANOVA comparison between sexes with Class II and Class III malocclusions showed greater expression of CRYAB (p=0.005) in males with Class II. Expression was likewise greater in males with Class III malocclusion than in females with Class III (p<0.01). Among different age groups, subjects 25 years of age or younger had significantly (p value=0.025) increased expression of CRYAB gene. There were no significant differences for genotypes or facial asymmetry. / Oral Biology

Dentistry

Genetics

Alpha-b-crystallin

Malocclusion

Tmd-myalgia

Distribution of αB-Crystallin in the Central Retina and Optic Nerve Head of Different Mammals and its Changes during Outer and Inner Retinal Degeneration

May, Christian Albrecht

11 July 2014

Purpose: To investigate species differences in the distribution and localization of alpha B-crystallin (ABC) in the normal retina and optic nerve head region, and to describe changes during outer and inner retina degeneration. Material and methods: Animals studied included mice, rats, cats, pigs, cows, and monkeys. Sections of the optic nerve and central retina were labeled with antibodies against ABC and glial fibrillary acidic protein (GFAP). Results: ABC was located in astrocytes and Muller cells with different intensities. During outer retina degeneration (dystrophic rat and Abyssinian cat), only late stages showed an increase in ABC in the retina and optic nerve head. Inner retina degeneration in the glaucoma mouse model showed no increase of ABC. In the monkey glaucoma model, only the innermost layer of the optic nerve head showed increased labeling for ABC. Conclusions: The distribution of ABC is species dependent and is (excluding the mouse) present in the nerve fiber layer of the retina and in the optic nerve head (localization of astrocytes). Chronic retinal degeneration does not necessarily lead to an over-expression of ABC. While in outer retinal degeneration induction was predominantly present in late stages, pressure-induced glaucoma led to a specific increase in ABC already in early stages indicating a local stress-response in this region.

Alpha-B-Crystallin

Astrozyt

Sehnerv

Retina

TU Dresden

Publikationsfonds

Alpha B-crystallin

Astrocytes

Optic nerve

Central retina

Technical University Dresden

Publication funds

ddc:610

rvk:XA 10000

Distribution of αB-Crystallin in the Central Retina and Optic Nerve Head of Different Mammals and its Changes during Outer and Inner Retinal Degeneration

May, Christian Albrecht

11 July 2014

Purpose: To investigate species differences in the distribution and localization of alpha B-crystallin (ABC) in the normal retina and optic nerve head region, and to describe changes during outer and inner retina degeneration. Material and methods: Animals studied included mice, rats, cats, pigs, cows, and monkeys. Sections of the optic nerve and central retina were labeled with antibodies against ABC and glial fibrillary acidic protein (GFAP). Results: ABC was located in astrocytes and Muller cells with different intensities. During outer retina degeneration (dystrophic rat and Abyssinian cat), only late stages showed an increase in ABC in the retina and optic nerve head. Inner retina degeneration in the glaucoma mouse model showed no increase of ABC. In the monkey glaucoma model, only the innermost layer of the optic nerve head showed increased labeling for ABC. Conclusions: The distribution of ABC is species dependent and is (excluding the mouse) present in the nerve fiber layer of the retina and in the optic nerve head (localization of astrocytes). Chronic retinal degeneration does not necessarily lead to an over-expression of ABC. While in outer retinal degeneration induction was predominantly present in late stages, pressure-induced glaucoma led to a specific increase in ABC already in early stages indicating a local stress-response in this region.

info:eu-repo/classification/ddc/610

ddc:610

Beyond the limit

Mainz, Andi

26 October 2012

Strukturelle Untersuchungen mittels Lösungs-NMR Spektroskopie sind für supramolekulare Maschinen mit Molekulargewichten von mehr als 150 kDa nur beschränkt möglich. Die Festkörper-NMR mit Probenrotation im sogenannten magischen Winkel (MAS) stellt dagegen eine molekulargewichtsunabhängige Methode dar. Im Rahmen dieser Arbeit wurde eine neue Methode entwickelt, die die MAS NMR Spektroskopie an supramolekularen Komplexen in Lösung erlaubt. Proteinlösungen bilden demnach durch MAS und dessen Ultrazentrifugationseffekt homogene Proteinsedimente aus, in denen die rotatorische Diffusion großer Proteinkomplexe überwiegend aufgehoben ist. Auf diese Weise können klassische Festkörper-NMR Methoden angewandt werden, ohne dass Präzipitations- oder Kristallisationsverfahren erforderlich sind. In Kombination mit Proteindeuterierung, Protonendetektion sowie paramagnetischer Relaxationsverstärkung ermöglichte diese neuartige Methode die Zuordnung von Rückgrat-Amidresonanzen des 20S Proteasoms mit einem Molekulargewicht von 1,1 MDa. Weiterhin wurde diese Methode zur Untersuchung des kleinen Hitzeschockproteins alpha-B-Crystallin und dessen Cu(II)-Bindungseigenschaften genutzt. Das Chaperon (600 kDa) spielt eine wesentliche Rolle in der zellulären Proteinhomeostase. Verschiedenste NMR Techniken und andere biophysikalische Methoden zeigen, dass die konservierte alpha-Crystallin-Domäne ein Cu(II)-Ion nahe der Monomer-Monomer Interaktionsfläche mit pikomolarer Affinität bindet. Die Cu(II)-induzierte Freilegung von Substrat-Interaktionsflächen und Veränderungen in der dynamischen Quartärstruktur modulieren so die oligomere Architektur und die Chaperonaktivität von alpha-B-Crystallin. Die hier erstmals beschriebene MAS NMR Spektroskopie von sedimentierten Biomolekülen legt einen wichtigen Grundstein für zukünftige Struktur- und Dynamikuntersuchungen an großen molekularen Maschinen. / Structural investigations of large biomolecules by solution-state NMR are challenging in case the molecular weight of the complex exceeds 150 kDa. Magic-angle-spinning (MAS) solid-state NMR is a powerful tool for the characterization of biomolecular systems irrespective of their molecular weight. In this work, an approach was developed, which enables the investigation of supramolecular modules by MAS NMR. Protein solutions can yield fairly homogeneous sediments due to the ultracentrifugal forces during MAS. Since rotational diffusion is impaired, typical solid-state NMR techniques can thus be applied without the need of precipitation or crystallization. This new approach in combination with protein deuteration, proton-detection and paramagnetic relaxation enhancement enabled the observation and the assignment of backbone amide resonances of a 20S proteasome assembly with a molecular weight of 1.1 MDa. Similarly, the approach was used to characterize the small heat-shock protein alpha-B-crystallin with respect to its Cu(II)-dependent chaperone activity. The chaperone (600 kDa) plays an essential role in cellular protein homeostasis. We show that the conserved alpha-crystallin core domain is the elementary Cu(II)-binding unit specifically coordinating one Cu(II) ion near to the dimer interface with picomolar binding affinity. We suggest that Cu(II)-binding unblocks potential client binding sites and alters quaternary dynamics of both the dimeric building block as well as the higher-order assemblies of alpha-B-crystallin. In summary, MAS NMR employed to biomolecules in solution is a very promising tool to explore structural and dynamic properties of large biological machines with no upper size limit.

Magic-angle-spinning NMR

Proteinkomplexe

alpha-B-Crystallin

Chaperone

Kleine Hitzeschockproteine

Kupferbindung

Alzheimer Krankheit

Beta-Amyloid

magic-angle-spinning NMR

protein complexes

alpha-B-crystallin

chaperones

small heat-shock proteins

copper binding

alzheimers disease

beta amyloid

570 Biowissenschaften, Biologie

32 Biologie

VG 9500

ddc:570