Characterization of a Novel Model of Lumbar Ligamentum Flavum Hypertrophy in Bipedal Standing Mice.

OBJECTIVE: To explore the main causes of hypertrophied ligamentum flavum (HLF) and the possibility of using bipedal standing mouse model to simulate the pathological changes in human HLF. METHODS: Thirty-two 8-week-old C57BL/6 male mice were randomly assigned to the experimental group (n = 16) and control group (n = 16). In the experimental group, mice were induced to adopt a bipedal standing posture by their hydrophobia. The experimental mice were maintained bipedal standing for 8 h a day with an interval of 2 h to consume food and water. The control mice were placed in a similar environment without bipedal standing. Eight 18-month-old C57BL/6 male mice were compared to evaluate the LF degeneration due to aging factor. Three-dimensional (3D) reconstruction and finite element models were carried out to analyze the stress and strain distribution of the mouse LF in sprawling and bipedal standing postures. Hematoxylin and Eosin (HE), Verhoeff-Van Gieson (VVG), and immunohistochemistry (IHC) staining were used to evaluate the LF degeneration of mice and humans. RT-qPCR and immunofluorescence analysis were used to evaluate the expressions of fibrosis-related factors and inflammatory cytokines of COL1A1, COL3A1, α-SMA, MMP2, IL-1ß, and COX-2. RESULTS: The von Mises stress (8.85 × 10-2 MPa) and maximum principal strain (6.64 × 10-1 ) in LF were increased 4944 and 7703 times, respectively, in bipedal standing mice. HE staining showed that the mouse LF area was greater in the bipedal standing 10-week-old group ([10.01 ± 2.93] × 104 µm2 ) than that in the control group ([3.76 ± 1.87] × 104 µm2 ) and 18-month-old aged group ([6.09 ± 2.70] × 104 µm2 ). VVG staining showed that the HLF of mice (3.23 ± 0.58) and humans (2.23 ± 0.31) had a similar loss of elastic fibers and an increase in collagen fibers. The cell density was higher during the process of HLF in mice (39.63 ± 4.81) and humans (23.25 ± 2.05). IHC staining showed that the number of α-SMA positive cells were significantly increased in HLF of mice (1.63 ± 0.74) and humans (3.50 ± 1.85). The expressions of inflammatory cytokines and fibrosis-related factors of COL1A1, COL3A1, α-SMA, MMP2, IL-1ß, and COX-2 were consistently higher in bipedal standing group than the control group. CONCLUSION: Our study suggests that 3D finite element models can help analyze the abnormal stress and strain distributions of LF in modeling mice. Mechanical stress is the main cause of hypertrophied ligamentum flavum compared to aging. The bipedal standing mice model can reflect the pathological characteristics of human HLF. The bipedal standing mice model can provide a standardized condition to elucidate the molecular mechanisms of mechanical stress-induced HLF in vivo.

Relationship between the location of ligamentum flavum hypertrophy and its stress in finite element analysis.

OBJECTIVE: To quantitatively describe the stress of the ligamentum flavum (LF) using the finite element method and to compare the stress at different parts of the healthy LF. METHODS: Based on the high resolution computed tomography imaging data of a healthy 22-year-old man, three-dimensional nonlinear L4-5 lumbar finite element model (FEM) representing intact condition was developed. The LF, as the object of the present research, was incorporated into the spinal model in the form of solid three-dimensional structure. The model's validity is verified by comparing its biomechanical indices, such as range of motion and axial compression pressure displacement, with published results under specific loading conditions. To authenticate the accuracy of the solid LF, the lamina attachments, the central cross-section, and other anatomy indicators were compared with figures in the published literature. After the average and maximum von Mises stress on the surface of LF under various working conditions were measured using ANSYS and AutoCAD software, the surface stress difference in the LF between the ventral and dorsal sides as well as the lateral and lamina parts were determined. RESULTS: The FEM predicted a similar tendency for biomechanical indices as shown in previous studies. The lamina attachments, the central cross-section, and the height as well as the width of the LF in the healthy FEM were in accordance with published results. In the healthy model, the average and maximum von Mises stress in the shallow layer of the LF were, respectively, 1.40, 2.28, 1.76, 1.48, 1.38 and 1.79, 2.41, 1.46, 1.42, 1.71 times that in the deep layer under a compressive preload of 500 N incorporated with flexion, extension, and lateral and rotational moments (10 Nm). The most conspicuous difference in surface stress was observed with the flexion motion, with a nearly 241% difference in the maximum stress and a 228% difference in the average stress compared to those in other states. As far as the whole dorsal side of the LF was concerned, the maximum surface stress was almost all concentrated in the dorsal neighboring facet joint portion. In addition, the maximum and average stress were, respectively, 77%, 72%, 15%, 11%, 71% and 153%, 39%, 54%, 200%, 212% higher in the lateral part than in the lamina part. CONCLUSION: Based on the predisposition of LF hypertrophy in the human spine and the stress distribution of this study, the positive correlation between LF hypertrophy and its stress was confirmed.

Molecular cloning and nutrient regulation analysis of long chain acyl-CoA synthetase 1 gene in grass carp, Ctenopharyngodon idella L.

Long chain acyl-CoA synthetase 1 (ACSL1), a key regulatory enzyme of fatty acid metabolism, catalyzes the conversion of long-chain fatty acids to acyl-coenzyme A. The full-length cDNAs of ACSL1a and ACSL1b were cloned from the liver of a grass carp. Both cDNAs contained a 2094bp open reading frame encoding 697 amino acids. Amino acid sequence alignment showed that ACSL1a shared 73.5% sequence identity with ACSL1b. Each of the two ACSL1s proteins had a transmembrane domain, a P-loop domain, and L-, A-, and G-motifs, which were relatively conserved in comparison to other vertebrates. Relative expression profile of ACSL1 mRNAs in different tissues indicated that ACSL1a is highly expressed in heart, mesenteric adipose, and brain tissues, whereas ACSL1b is highly expressed in heart, white muscle, foregut, and liver tissues. Nutrient regulation research showed that the expression levels of ACSL1a and ACSL1b were significantly down-regulated when 3, 6, and 9% fish oil were added in diet of grass carp as compared to the control group. However, no significant difference in the levels of ACSL1 mRNA was observed between the experimental groups. This study demonstrated the relationship between ACSL1a and ACSL1b genes in grass carp and laid a foundation for further research on ACSL family members in other species.

Molecular characterization and tissue-specific expression of the acetyl-CoA carboxylase α gene from Grass carp, Ctenopharyngodon idella.

Acetyl-CoA carboxylase α (ACC1), the major regulatory enzyme of fatty acid biosynthesis, catalyzes the conversion of acetyl-CoA to malonyl-CoA. The full-length cDNA coding ACC1 isoform was cloned from liver of grass carp. The cDNA obtained was 7515bp with a 7173bp open reading frame encoding 2389 amino acids. The ACC1 protein has a calculated molecular weight of 269.2kDa and isoelectric point of 6.23. Tissue distribution of ACC1 mRNA in brain, mesenteric adipose, spleen, white muscle and liver of grass carp was analyzed by real-time PCR method using ß-actin as an internal control for cDNA normalization. The results showed that the expressions of ACC1 mRNA were detected in all examined tissues. Relative expression profile of ACC1 mRNA in liver normalized with ß-actin level was 15, 92, 135 and 165-fold compared with the level in brain, white muscle, mesenteric adipose and spleen, respectively. In addition, we present evidence for the presence of two isoforms of ACC1 (265.7kDa and 267.2kDa) in grass carp liver that differ from the 269.2kDa ACC1 by the absence of 34 and 15 amino acids. In conclusion, the liver is one of the main ACC1 producing tissues in grass carp and ACC1 gene was highly homologous to that of mammals.

cDNA sequence and tissues expression analysis of lipoprotein lipase from common carp (Cyprinus carpio Var. Jian).

A full-length cDNA coding lipoprotein lipase (LPL) was cloned from liver of adult common carp (Cyprinus carpio Var. Jian) by RT-PCR and rapid amplification of cDNA ends (RACE) approaches. The cDNA obtained was 2,411 bp long with a 1,524 bp open reading frame (ORF) encoding 507 amino acids. This amino acid sequence contains two structural regions: N-terminus (24-354 residues) and C-terminus (355-507 residues). Before N-terminus, 1-23 residues is signal peptide, 6-23 residues is transmembrance helix. At N-terminus, some conversed functional sites were found, including two N-linked glycosylation sites Asn(41) and Asn(88); one catalytic triad Ser(174), Asp(198) and His(283); one conserved heparin-binding site Arg(321) to Arg(324) (RKNR); eight cysteines residues Cys(69) and Cys(82), Cys(258) and Cys(281), Cys(306) and Cys(325), Cys(317) and Cys(320) which are involved in four disulfide bridges; one polypeptide "lid" that participates in substrate specificity. At C-terminus, Asn(401) is another N-linked glycosylation site, and Trp(434) and Trp(435) (WW) is lipid-binding site. The amino acid sequence has a high similarity, and shows similar structural features to LPL of other species. Tissue distribution of LPL mRNA in liver, head kidney, mesenteric adipose tissue, heart and white muscle of common carp was analyzed by semi-quantitative RT-PCR method using beta-actin gene as internal control. The result showed that the expressions of LPL mRNA were detected in all examined tissues of common carp. The expression levels of LPL in the mesenteric adipose tissue was highest among these tissues, following in liver and head kidney, and the lowest expression was found in heart and white muscle.

Molecular cloning and tissue distribution of lipoprotein lipase full-length cDNA from Pengze crucian carp (Carassius auratus var. Pengze).

A full-length cDNA coding lipoprotein lipase (LPL) was cloned from liver of adult Pengze crucian carp (Carassius auratus var. Pengze) by RT-PCR and rapid amplification of cDNA ends (RACE) approaches. The cDNA obtained was 1877 bp long with a 1524 bp open reading frame (ORF) encoding 507 amino acids, including a putative signal peptide of 23 amino acids long. The deduced amino acid sequence has a high similarity and shows similar structural features to LPL of other species. The LPL protein has a calculated molecular mass of 57.7 kDa and isolectric point of 7.85. Tissue distribution of LPL mRNA in mesenteric adipose tissue, liver, heart, head kidney and white muscle of adult Pengze crucian carp was analyzed by semi-quantitative RT-PCR method using beta-actin gene as internal control, the result showed that this gene was ubiquitously expressed in all tissues tested with the highest abundance in mesenteric adipose tissue, following in head kidney and liver, and the lowest expression was found in heart and white muscle.