Your search keyword '"Czernik, Piotr J."' showing total 11 results

1. Diabetes increases risk of lumbar spinal fusion complications: association with altered structure of newly formed bone at the fusion site.

Author

Wilson, Claire, Czernik, Piotr J, Elgafy, Hossein, Khuder, Sadik, Serdahely, Kevin, Rowland, Andrea, and Lecka-Czernik, Beata

Subjects

SPINAL fusion, HEALTH facilities, REOPERATION, DIABETES, SPINE diseases, LUMBAR vertebrae

Abstract

Diabetes predisposes to spine degenerative diseases often requiring surgical intervention. However, the statistics on the prevalence of spinal fusion success and clinical indications leading to the revision surgery in diabetes are conflicting. The purpose of the presented retrospective observational study was to determine the link between diabetes and lumbar spinal fusion complications using a database of patients (n  = 552, 45% male, age 54 ± 13.7 years) residing in the same community and receiving care at the same health care facility. Outcome measures included clinical indications and calculated risk ratio (RR) for revision surgery in diabetes. Paravertebral tissue recovered from a non-union site of diabetic and nondiabetic patients was analyzed for microstructure of newly formed bone. Diabetes increased the RR for revision surgery due to non-union complications (2.80; 95% CI, 1.12–7.02) and degenerative processes in adjacent spine segments (2.26; 95% CI, 1.45–3.53). In diabetes, a risk of revision surgery exceeded the RR for primary spinal fusion surgery by 44% (2.36 [95% CI, 1.58–3.52] vs 1.64 [95% CI, 1.16–2.31]), which was already 2-fold higher than diabetes prevalence in the studied community. Micro-CT of bony fragments found in the paravertebral tissue harvested during revision surgery revealed structural differences suggesting that newly formed bone in diabetic patients may be of compromised quality, as compared with that in nondiabetic patients. In conclusion, diabetes significantly increases the risk of unsuccessful lumbar spine fusion outcome requiring revision surgery. Diabetes predisposes to the degeneration of adjacent spine segments and pseudoarthrosis at the fusion sites, and affects the structure of newly formed bone needed to stabilize fusion. [ABSTRACT FROM AUTHOR]

Published

2024

2. Osteocytes contribute via nuclear receptor PPAR-alpha to maintenance of bone and systemic energy metabolism.

Author

Chougule, Amit, Baroi, Sudipta, Czernik, Piotr J., Crowe, Emily, Mi Ra Chang, Griffin, Patrick R., and Lecka-Czernik, Beata

Subjects

ENERGY metabolism, OSTEOCYTES, BONE metabolism, BONE marrow cells, PARACRINE mechanisms, BONE cells, OSTEOBLASTS

Abstract

Introduction: The view that bone and energy metabolism are integrated by common regulatory mechanisms is broadly accepted and supported by multiple strands of evidence. This includes the well-characterized role of the PPARg nuclear receptor, which is a common denominator in energy metabolism and bone metabolism. Little is known, however, about the role of PPARa nuclear receptor, a major regulator of lipid metabolism in other organs, in bone. Methods: A side-by-side comparative study of 5-15 mo old mice with global PPARa deficiency (aKO) and mice with osteocyte-specific PPARa deficiency (aOTKO) in order to parse out the various activities of PPARa in the skeleton that are of local and systemic significance. This study included transcriptome analysis of PPARa-deficient osteocytes, and analyses of bone mass and bone microarchitecture, systemic energy metabolism with indirect calorimetry, and differentiation potential of hematopoietic and mesenchymal bone cell progenitors. These analyses were paired with in vitro studies of either intact or silenced for PPARa MLO-A5 cells to determine PPARa role in osteocyte bioenergetics. Results: In osteocytes, PPARa controls large number of transcripts coding for signaling and secreted proteins which may regulate bone microenvironment and peripheral fat metabolism. In addition, PPARa in osteocytes controls their bioenergetics and mitochondrial response to stress, which constitutes up to 40% of total PPARa contribution to the global energy metabolism. Similarly to aKO mice, the metabolic phenotype of aOTKO mice (both males and females) is age-dependent. In younger mice, osteocyte metabolism contributes positively to global energetics, however, with aging the high-energy phenotype reverts to a low-energy phenotype and obesity develops, suggesting a longitudinal negative effect of impaired lipid metabolism and mitochondrial dysfunction in osteocytes deficient in PPARa. However, bone phenotype was not affected in aOTKO mice except in the form of an increased volume of marrow adipose tissue in males. In contrast, global PPARa deficiency in aKO mice led to enlarged bone diameter with a proportional increase in number of trabeculae and enlarged marrow Introduction: The view that bone and energy metabolism are integrated by common regulatory mechanisms is broadly accepted and supported by multiple strands of evidence. This includes the well-characterized role of the PPARg nuclear receptor, which is a common denominator in energy metabolism and bone metabolism. Little is known, however, about the role of PPARa nuclear receptor, a major regulator of lipid metabolism in other organs, in bone. Methods: A side-by-side comparative study of 5-15 mo old mice with global PPARa deficiency (aKO) and mice with osteocyte-specific PPARa deficiency (aOTKO) in order to parse out the various activities of PPARa in the skeleton that are of local and systemic significance. This study included transcriptome analysis of PPARa-deficient osteocytes, and analyses of bone mass and bone microarchitecture, systemic energy metabolism with indirect calorimetry, and differentiation potential of hematopoietic and mesenchymal bone cell progenitors. These analyses were paired with in vitro studies of either intact or silenced for PPARa MLO-A5 cells to determine PPARa role in osteocyte bioenergetics. Results: In osteocytes, PPARa controls large number of transcripts coding for signaling and secreted proteins which may regulate bone microenvironment and peripheral fat metabolism. In addition, PPARa in osteocytes controls their bioenergetics and mitochondrial response to stress, which constitutes up to 40% of total PPARa contribution to the global energy metabolism. Similarly to aKO mice, the metabolic phenotype of aOTKO mice (both males and females) is age-dependent. In younger mice, osteocyte metabolism contributes positively to global energetics, however, with aging the high-energy phenotype reverts to a low-energy phenotype and obesity develops, suggesting a longitudinal negative effect of impaired lipid metabolism and mitochondrial dysfunction in osteocytes deficient in PPARa. However, bone phenotype was not affected in aOTKO mice except in the form of an increased volume of marrow adipose tissue in males. In contrast, global PPARa deficiency in aKO mice led to enlarged bone diameter with a proportional increase in number of trabeculae and enlarged marrow Introduction: The view that bone and energy metabolism are integrated by common regulatory mechanisms is broadly accepted and supported by multiple strands of evidence. This includes the well-characterized role of the PPARg nuclear receptor, which is a common denominator in energy metabolism and bone metabolism. Little is known, however, about the role of PPARa nuclear receptor, a major regulator of lipid metabolism in other organs, in bone. Methods: A side-by-side comparative study of 5-15 mo old mice with global PPARa deficiency (aKO) and mice with osteocyte-specific PPARa deficiency (aOTKO) in order to parse out the various activities of PPARa in the skeleton that are of local and systemic significance. This study included transcriptome analysis of PPARa-deficient osteocytes, and analyses of bone mass and bone microarchitecture, systemic energy metabolism with indirect calorimetry, and differentiation potential of hematopoietic and mesenchymal bone cell progenitors. These analyses were paired with in vitro studies of either intact or silenced for PPARa MLO-A5 cells to determine PPARa role in osteocyte bioenergetics. Results: In osteocytes, PPARa controls large number of transcripts coding for signaling and secreted proteins which may regulate bone microenvironment and peripheral fat metabolism. In addition, PPARa in osteocytes controls their bioenergetics and mitochondrial response to stress, which constitutes up to 40% of total PPARa contribution to the global energy metabolism. Similarly to aKO mice, the metabolic phenotype of aOTKO mice (both males and females) is age-dependent. In younger mice, osteocyte metabolism contributes positively to global energetics, however, with aging the high-energy phenotype reverts to a low-energy phenotype and obesity develops, suggesting a longitudinal negative effect of impaired lipid metabolism and mitochondrial dysfunction in osteocytes deficient in PPARa. However, bone phenotype was not affected in aOTKO mice except in the form of an increased volume of marrow adipose tissue in males. In contrast, global PPARa deficiency in aKO mice led to enlarged bone diameter with a proportional increase in number of trabeculae and enlarged marrow cavities; it also altered differentiation of hematopoietic and mesenchymal marrow cells toward osteoclast, osteoblast and adipocyte lineages, respectively. Discussion: PPARa role in bone is multileveled and complex. In osteocytes, PPARa controls the bioenergetics of these cells, which significantly contributes to systemic energy metabolism and their endocrine/paracrine function in controlling marrow adiposity and peripheral fat metabolism. [ABSTRACT FROM AUTHOR]

Published

2023

3. Reconstitution of the host holobiont in germ-free born male rats acutely increases bone growth and affects marrow cellular content.

Author

Czernik, Piotr J., Golonka, Rachel M., Chakraborty, Saroj, Beng San Yeoh, Abokor, Ahmed A., Saha, Piu, Ji-Youn Yeo, Mell, Blair, Xi Cheng, Baroi, Sudipta, Yuan Tian, Patterson, Andrew D., Joe, Bina, Vijay-Kumar, Matam, and Lecka-Czernik, Beata

Subjects

BONE growth, BONE lengthening (Orthopedics), BONE density, RADIAL bone, SHORT-chain fatty acids, GROWTH plate

Abstract

Integration of microbiota in a host begins at birth and progresses during adolescence, forming a multidirectional system of physiological interactions. Here, we present an instantaneous effect of natural, bacterial gut colonization on the acceleration of longitudinal and radial bone growth in germ-free born, 7-wk-old male rats. Changes in bone mass and structure were analyzed after 10 days following the onset of colonization through cohousing with conventional rats and revealed unprecedented acceleration of bone accrual in cortical and trabecular compartments, increased bone tissue mineral density, improved proliferation and hypertrophy of growth plate chondrocytes, bone lengthening, and preferential deposition of periosteal bone in the tibia diaphysis. In addition, the number of small in size adipocytes increased, whereas the number of megakaryocytes decreased, in the bone marrow of conventionalized germ-free rats indicating that not only bone mass but also bone marrow environment is under control of gut microbiota signaling. The changes in bone status paralleled with a positive shift in microbiota composition toward short-chain fatty acids (SCFA)-producing microbes and a considerable increase in cecal SCFA concentrations, specifically butyr-ate. Furthermore, reconstitution of the host holobiont increased hepatic expression of IGF-1 and its circulating levels. Elevated serum levels of 25-hydroxy vitamin D and alkaline phosphatase pointed toward an active process of bone formation. The acute stimulatory effect on bone growth occurred independently of body mass increase. Overall, the presented model of conventionalized germ-free rats could be used to study microbiota-based therapeutics for combatting dysbiosis-related bone disorders. [ABSTRACT FROM AUTHOR]

Published

2021

4. 14-3-3ζ: A suppressor of inflammatory arthritis.

Author

Kim, Joshua, Chun, Krista, McGowan, Jenna, Youjie Zhang, Czernik, Piotr J., Mell, Blair, Joe, Bina, Chattopadhyay, Saurabh, Holoshitz, Joseph, and Chakravarti, Ritu

Subjects

JOINTS (Anatomy), ARTHRITIS, RECOMBINANT proteins, COLLAGEN-induced arthritis, MESSENGER RNA, COMMERCIAL products, SPIDER silk

Abstract

Inflammatory arthritis (IA) is a common disease that affects millions of individuals worldwide. Proinflammatory events during IA pathogenesis are well studied; however, loss of protective immunity remains underexplored. Earlier, we reported that 14-3-3zeta (ζ) has a role in T-cell polarization and interleukin (IL)-17A signal transduction. Here, we demonstrate that 14-3-3ζ knockout (KO) rats develop early-onset severe arthritis in two independent models of IA, pristane-induced arthritis and collagen-induced arthritis. Arthritic 14-3-3ζ KO animals showed an increase in bone loss and immune cell infiltration in synovial joints. Induction of arthritis coincided with the loss of anti-14-3-3ζ antibodies; however, rescue experiments to supplement the 14-3-3ζ antibody by passive immunization did not suppress arthritis. Instead, 14-3-3ζ immunization during the presymptomatic phase resulted in significant suppression of arthritis in both wild-type and 14-3-3ζ KO animals. Mechanistically, 14-3-3ζ KO rats exhibited elevated inflammatory gene signatures at the messenger RNA and protein levels, particularly for IL-1β. Furthermore, the immunization with recombinant 14-3-3ζ protein suppressed IL-1β levels, significantly increased anti-14-3-3ζ antibody levels and collagen production, and preserved bone quality. The 14-3-3ζ protein increased collagen expression in primary rat mesenchymal cells. Together, our findings indicate that 14-3-3ζ causes immune suppression and extracellular remodeling, which lead to a previously unrecognized IA-suppressive function. [ABSTRACT FROM AUTHOR]

Published

2021

5. Nonenzymatic and Trophic Activities of Carboxypeptidase E Regulate Bone Mass and Bioenergetics of Skeletal Stem Cells in Mice.

Author

Chougule, Amit, Kolli, Vipula, Baroi, Sudipta, Ebraheim, Nabil, Czernik, Piotr J, Loh, Y Peng, and Lecka‐Czernik, Beata

Subjects

BONES, STEM cells, BIOENERGETICS, BONE marrow cells, MICE, OSTEOCLASTS

Abstract

Bone and energy metabolism are integrated by common regulatory mechanisms. Carboxypeptidase E (CPE), also known as obesity susceptibility protein or neurotrophic factor‐α1, is recognized for its function in processing prohormones, including proinsulin and pro‐opiomelanocortin polypeptide. Independent of its enzymatic activity, CPE may also act as a secreted factor with divergent roles in neuroprotection and cancer growth; however, its role in the regulation of bone mass and skeletal cell differentiation is unknown. Male mice with global deficiency in CPE are characterized with profound visceral obesity, low bone mass in both appendicular and axial skeleton, and high volume of marrow fat. Interestingly, although metabolic deficit of CPE KO mice develops early in life, bone deficit develops in older age, suggesting that CPE bone‐specific activities differ from its enzymatic activities. Indeed, mutated CPE knockin (mCPE KI) mice ectopically expressing CPE‐E342Q, a mutated protein lacking enzymatic activity, develop the same obese phenotype and accumulate the same volume of marrow fat as CPE KO mice, but their bone mass is normal. In addition, differentiation of marrow hematopoietic cells toward tartrate‐resistant acid phosphatase‐positive multinucleated osteoclasts is highly increased in CPE KO mice, but normal in mCPE KI mice. Moreover, in murine skeletal stem cells, nonenzymatic trophic CPE has activated ERK signaling, increased cell proliferation and increased mitochondrial activity. Treatment of preosteoblastic cells with intact or mutated recombinant CPE led to a transient accumulation of small lipid droplets, increased oxidative phosphorylation, and increased cellular dependence on fatty acids as fuel for energy production. In human marrow aspirates, CPE expression increases up to 30‐fold in osteogenic conditions. These findings suggest that nonenzymatic and trophic activities of CPE regulate bone mass, whereas marrow adiposity is controlled by CPE enzymatic activity. Thus, CPE can be positioned as a factor regulating simultaneously bone and energy metabolism through a combination of shared and distinct mechanisms. © 2020 The Authors. JBMR Plus published by Wiley Periodicals, Inc. on behalf of American Society for Bone and Mineral Research © 2020 The Authors. JBMR Plus published by Wiley Periodicals LLC. on behalf of American Society for Bone and Mineral Research. [ABSTRACT FROM AUTHOR]

Published

2020

6. Marrow Adipose Tissue: Skeletal Location, Sexual Dimorphism, and Response to Sex Steroid Deficiency.

Author

Lecka-Czernik, Beata, Stechschulte, Lance A., Czernik, Piotr J., Sherman, Shermel B., Shilong Huang, and Krings, Amrei

Subjects

SEXUAL dimorphism, ADIPOSE tissues, SEX hormones, OVARIECTOMY, BONE remodeling

Abstract

Marrow adipose tissue (MAT) is unique with respect to origin, metabolism, and function. MAT is characterized with high heterogeneity which correlates with skeletal location and bone metabolism. This fat depot is also highly sensitive to various hormonal, environmental, and pharmacologic cues to which it responds with changes in volume and/or metabolic phenotype. We have demonstrated previously that MAT has characteristics of both white (WAT) and brown (BAT)-like or beige adipose tissue, and that beige phenotype is attenuated with aging and in diabetes. Here, we extended our analysis by comparing MAT phenotype in different locations within a tibia bone of mature C57BL/6 mice and with respect to the presence of sex steroids in males and females. We report that MAT juxtaposed to trabecular bone of proximal tibia (pMAT) is characterized by elevated expression of beige fat markers including Ucp1, HoxC9, Prdm16, Tbx1, and Dio2, when compared with MAT located in distal tibia (dMAT). There is also a difference in tissue organization with adipocytes in proximal tibia being dispersed between trabeculae, while adipocytes in distal tibia being densely packed. Higher trabecular bone mass (BV/TV) in males correlates with lower pMAT volume and higher expression of beige markers in the same location, when compared with females. However, there is no sexual divergence in the volume and transcriptional profile of dMAT. A removal of ovaries in females resulted in decreased cortical bone mass and increased volume of both pMAT and dMAT, as well as volume of gonadal WAT (gWAT). Increase in pMAT volume was associated with marked increase in Fabp4 and Adiponectin expression and relative decrease in beige fat gene markers. A removal of testes in males resulted in cortical and trabecular bone loss and the tendency to increased volume of both pMAT and dMAT, despite a loss of gWAT. Orchiectomy did not affect the expression of white and beige adipocyte gene markers. In conclusion, expression profile of beige adipocyte gene markers correlates with skeletal location of active bone remodeling and higher BV/TV, however bone loss resulted from sex steroid deficiency is not proportional to MAT expansion at the same skeletal location. [ABSTRACT FROM AUTHOR]

Published

2017

7. High-resolution mapping of a novel rat blood pressure locus on chromosome 9 to a region containing the Spp2 gene and colocalization of a QTL for bone mass.

Author

Ying Nie, Kumarasamy, Sivarajan, Waghulde, Harshal, Xi Cheng, Mell, Blair, Czernik, Piotr J., Lecka-Czernik, Beata, and Joe, Bina

Subjects

BLOOD pressure, CHROMOSOMES, LABORATORY rats, LOCUS (Genetics), HYPERTENSION, HIGH-salt diet

Abstract

Through linkage analysis of the Dahl salt-sensitive (S) rat and the spontaneously hypertensive rat (SHR), a blood pressure (BP) quantitative trait locus (QTL) was previously located on rat chromosome 9. Subsequent substitution mapping studies of this QTL revealed multiple BP QTLs within the originally identified logarithm of odds plot by linkage analysis. The focus of this study was on a 14.39 Mb region, the distal portion of which remained unmapped in our previous studies. High-resolution substitution mapping for a BP QTL in the setting of a high-salt diet indicated that an SHR-derived congenic segment of 787.9 kb containing the gene secreted phosphoprotein-2 (Spp2) lowered BP and urinary protein excretion. A nonsynonymous G/T polymorphism in the Spp2 gene was detected between the S and S.SHR congenic rats. A survey of 45 strains showed that the T allele was rare, being detected only in some substrains of SHR and WKY. Protein modeling prediction through SWISSPROT indicated that the predicted protein product of this variant was significantly altered. Importantly, in addition to improved cardiovascular and renal function, high salt-fed congenic animals carrying the SHR T variant of Spp2 had significantly lower bone mass and altered bone microarchitecture. Total bone volume and volume of trabecular bone, cortical thickness, and degree of mineralization of cortical bone were all significantly reduced in congenic rats. Our study points to opposing effects of a congenic segment containing the prioritized candidate gene Spp2 on BP and bone mass. [ABSTRACT FROM AUTHOR]

Published

2016

8. Partial Agonist, Telmisartan, Maintains PPARγ Serine 112 Phosphorylation, and Does Not Affect Osteoblast Differentiation and Bone Mass.

Author

Kolli, Vipula, Stechschulte, Lance A., Dowling, Abigail R., Rahman, Sima, Czernik, Piotr J., and Lecka-Czernik, Beata

Subjects

OSTEOBLAST metabolism, SERINE, PHOSPHORYLATION, BONE density, TRANSCRIPTION factors, ANTIHYPERTENSIVE agents, ROSIGLITAZONE, PEROXISOME proliferator-activated receptors, MESENCHYMAL stem cells

Abstract

Peroxisome proliferator activated receptor gamma (PPARγ) controls both glucose metabolism and an allocation of marrow mesenchymal stem cells (MSCs) toward osteoblast and adipocyte lineages. Its activity is determined by interaction with a ligand which directs posttranscriptional modifications of PPARγ protein including dephosphorylation of Ser112 and Ser273, which results in acquiring of pro-adipocytic and insulin-sensitizing activities, respectively. PPARγ full agonist TZD rosiglitazone (ROSI) decreases phosphorylation of both Ser112 and Ser273 and its prolonged use causes bone loss in part due to diversion of MSCs differentiation from osteoblastic toward adipocytic lineage. Telmisartan (TEL), an anti-hypertensive drug from the class of angiotensin receptor blockers, also acts as a partial PPARγ agonist with insulin-sensitizing and a weak pro-adipocytic activity. TEL decreased S273pPPARγ and did not affect S112pPPARγ levels in a model of marrow MSC differentiation, U-33/γ2 cells. In contrast to ROSI, TEL did not affect osteoblast phenotype and actively blocked ROSI-induced anti-osteoblastic activity and dephosphorylation of S112pPPARγ. The effect of TEL on bone was tested side-by-side with ROSI. In contrast to ROSI, TEL administration did not affect bone mass and bone biomechanical properties measured by micro-indentation method and did not induce fat accumulation in bone, and it partially protected from ROSI-induced bone loss. In addition, TEL induced “browning” of epididymal white adipose tissue marked by increased expression of UCP1, FoxC2, Wnt10b and IGFBP2 and increased overall energy expenditure. These studies point to the complexity of mechanisms by which PPARγ acquires anti-osteoblastic and pro-adipocytic activities and suggest an importance of Ser112 phosphorylation status as being a part of the mechanism regulating this process. These studies showed that TEL acts as a full PPARγ agonist for insulin-sensitizing activity and as a partial agonist/partial antagonist for pro-adipocytic and anti-osteoblastic activities. They also suggest a relationship between PPARγ fat “browning” activity and a lack of anti-osteoblastic activity. [ABSTRACT FROM AUTHOR]

Published

2014

9. β-Catenin Directly Sequesters Adipocytic and Insulin Sensitizing Activities but Not Osteoblastic Activity of PPARγ2 in Marrow Mesenchymal Stem Cells.

Author

Rahman, Sima, Czernik, Piotr J., Yalin Lu, and Lecka-Czernik, Beata

Subjects

HYPOGLYCEMIC agents, PANCREATIC secretions, HORMONES, INSULIN, STEM cells, BONE marrow

Abstract

Lineage allocation of the marrow mesenchymal stem cells (MSCs) to osteoblasts and adipocytes is dependent on both Wnt signaling and PPARγ2 activity. Activation of PPARγ2, an essential regulator of energy metabolism and insulin sensitivity, stimulates adipocyte and suppresses osteoblast differentiation and bone formation, and correlates with decreased bone mass and increased fracture rate. In contrast, activation of Wnt signaling promotes osteoblast differentiation, augments bone accrual and reduces total body fat. This study examined the cross-talk between PPARγ2 and β-catenin, a key mediator of canonical Wnt signaling, on MSC lineage determination. Rosiglitazone-activated PPARγ2 induced rapid proteolytic degradation of β-catenin, which was prevented by either inhibiting glycogen synthase kinase 3 beta (GSK3b) activity, or blocking pro-adipocytic activity of PPARγ2 using selective antagonist GW9662 or mutation within PPARγ2 protein. Stabilization of β-catenin suppressed PPARγ2 pro-adipocytic but not anti-osteoblastic activity. Moreover, β-catenin stabilization decreased PPARγ2-mediated insulin signaling as measured by insulin receptor and FoxO1 gene expression, and protein levels of phosphorylated Akt (pAkt). Cellular knockdown of β-catenin with siRNA increased expression of adipocyte but did not affect osteoblast gene markers. Interestingly, the expression of Wnt10b was suppressed by anti-osteoblastic, but not by pro-adipocytic activity of PPARγ2. Moreover, β-catenin stabilization in the presence of activated PPARγ2 did not restore Wnt10b expression indicating a dominant role of PPARγ2 in negative regulation of pro-osteoblastic activity of Wnt signaling. In conclusion, β-catenin and PPARγ2 are in cross-talk which results in sequestration of pro-adipocytic and insulin sensitizing activity. The anti-osteoblastic activity of PPARγ2 is independent of this interaction. [ABSTRACT FROM AUTHOR]

Published

2012

10. PPARγ2 nuclear receptor controls multiple regulatory pathways of osteoblast differentiation from marrow mesenchymal stem cells.

Author

Shockley, Keith R., Lazarenko, Oxana P., Czernik, Piotr J., Rosen, Clifford J., Churchill, Gary A., and Lecka-Czernik, Beata

Published

2009

11. STRUCTURAL AND FUNCTIONAL STUDIES OF UDP-GLUCURONOSYLTRANSFERASES*.

Author

RADOMINSKA-PANDYA, ANNA, CZERNIK, PIOTR J., LITTLE, JOANNA M., BATTAGLIA, ERIC, and MACKENZIE, PETER I.

Subjects

GLUCURONOSYLTRANSFERASE, DRUG metabolism

Abstract

In this review, current information on the substrate specificities of UGT1A and 2B family isoforms is discussed. Recent findings with regard to UGT structure and topology are presented, including a dynamic topological model of UGTs in the ER. Evidence from experiments on UGT interactions with inhibitors directed at specific amino acids, photoaffinity labeling, and analysis of amino acid alignments suggest that UDP–GIcUA interacts with residues in both the N- and C-terminal domains, whereas aglycon binding sites are localized in the N-terminal domain. The amino acids identified so far as crucial for substrate binding and catalysis are arginine, lysine, histidine, proline, and residues containing carboxylic acid. Site-directed mutagenesis experiments are critical for unambiguous identification of the active-site architecture. [ABSTRACT FROM AUTHOR]

Published

1999