[Retracted] Knockdown of circ_0001883 may inhibit epithelial‑mesenchymal transition in laryngeal squamous cell carcinoma via the miR‑125‑5p/PI3K/AKT axis

[This retracts the article DOI: 10.3892/etm.2021.10440.].

Knockdown of circ_0001883 may inhibit epithelial-mesenchymal transition in laryngeal squamous cell carcinoma via the miR-125-5p/PI3K/AKT axis

Laryngeal squamous cell carcinoma (LSCC) is a malignant tumor with increasing incidence and poor prognosis. Circular RNAs (circRNAs) are known to modulate tumorigenesis and cancer development that may function through microRNAs (miRs). The aim of the present study was to investigate the functional roles of circ_0001883 in LSCC and the underlying molecular mechanism. The expression of circ_0001883 was upregulated and measured using reverse transcription-quantitative PCR (RT-qPCR) and RNase R. miR-125b-5p expression was downregulated in LSCC tissues and cells as determined using RT-qPCR. Subsequently, knockdown of circ_0001883 inhibited LSCC cell migration, invasion and epithelial-mesenchymal transition (EMT), which were tested by wound healing assays, Transwell assays and western blotting, respectively. Bioinformatics analysis predicted that circ_0001883 was a sponge of miR-125b-5p, which was verified using a dual-luciferase reporter assay. Knockdown of circ_0001883 played a functional role by sponging miR-125b-5p. Additionally, circ_0001883 and miR-125b-5p influenced phosphorylation of PI3K and AKT, detected via western blotting. In an in vivo study, knockdown of circ_0001883 reduced tumor volume and weight in mice, along with enhanced miR-125b-5p and E-cadherin expression levels, and decreased N-cadherin, phosphorylated (p)-PI3K/PI3K and p-AKT/AKT ratios. In conclusion, knockdown of circ_0001883 inhibited cell migration, invasion and EMT of LSCC by sponging miR-125b-5p. This is hypothesized to be via the PI3K/AKT signaling pathway, which suggested that circ_0001883 has potential for LSCC therapy.

Noncoplanar Versus Coplanar Intensity-Modulated Radiation Therapy (IMRT) for Protection of the Lip and Buccal Mucosa

Objective:

In this study, by comparing coplanar and noncoplanar intensity-modulated radiation therapy (IMRT) treatment planning in treating tongue cancer, the significance of noncoplanar fields in the protection of the lip and buccal mucosa was determined, and a reasonable solution was selected.

Methods:

Forty-eight tongue cancer patients treated from June 2019 to February 2021 were selected and randomly divided into a coplanar field group and a noncoplanar field group. The mucosal dose limit changed from 15 Gy to 45 Gy for comparison of the two treatment plans. The evaluation indicators (conformal index (CI); homogeneity index (HI); D5, D50, and D98 of the target volume; and the dose of normal tissues) were calculated under different mucosal dose limits. The clinical observation of the lip and buccal mucosa of 48 cases was monitored and graded carefully according to NCI-CTCAE V4.0. Statistical analyses were performed.

Results:

The differences in CI, HI, D98, D50 and D5 between the two groups in the target volume tended to decrease when the mucosal dose limit was less than 30 Gy, with a significant difference (P < 0.05). When the limit exceeded 30 Gy, significant differences in other indicators except CI (P < 0.05) were still noted. In normal tissue, differences in doses between the two groups existed when the mucosal limit was less than 20 Gy, with a significant difference (P < 0.05). When the limit exceeded 20 Gy, no significant difference was noted. Patients in the noncoplanar group showed significantly better results than those in the other group in terms of the radiation-related toxicity of the lip and cheek membrane(P < 0.001).

Conclusions:

Compared with coplanar field radiotherapy, noncoplanar field radiotherapy can effectively reduce the exposure dose to the lip and buccal mucosa. The application of noncoplanar treatment plans exhibits good clinical significance and deserves to be promoted.

Improved Methods to Generate Spheroid Cultures from Tumor Cells, Tumor Cells & Fibroblasts or Tumor-Fragments: Microenvironment, Microvesicles and MiRNA

Diagnostic and prognostic indicators are key components to achieve the goal of personalized cancer therapy. Two distinct approaches to this goal include predicting response by genetic analysis and direct testing of possible therapies using cultures derived from biopsy specimens. Optimally, the latter method requires a rapid assessment, but growing xenograft tumors or developing patient-derived cell lines can involve a great deal of time and expense. Furthermore, tumor cells have much different responses when grown in 2D versus 3D tissue environments. Using a modification of existing methods, we show that it is possible to make tumor-fragment (TF) spheroids in only 2–3 days. TF spheroids appear to closely model characteristics of the original tumor and may be used to assess critical therapy-modulating features of the microenvironment such as hypoxia. A similar method allows the reproducible development of spheroids from mixed tumor cells and fibroblasts (mixed-cell spheroids). Prior literature reports have shown highly variable development and properties of mixed-cell spheroids and this has hampered the detailed study of how individual tumor-cell components interact. In this study, we illustrate this approach and describe similarities and differences using two tumor models (U87 glioma and SQ20B squamous-cell carcinoma) with supporting data from additional cell lines. We show that U87 and SQ20B spheroids predict a key microenvironmental factor in tumors (hypoxia) and that SQ20B cells and spheroids generate similar numbers of microvesicles. We also present pilot data for miRNA expression under conditions of cells, tumors, and TF spheroids.

Labyrinthine Sequestrum

Labyrinthine sequestrum, a rare form of labyrinthitis, is highly distinct from the more commonly encountered labyrinthitis ossificans based on its unique clinical, radiologic, and histologic characteristics. The study included 4 such patients who had undergone clinical and laboratory investigations, computed tomography (CT), and magnetic resonance imaging (MRI) assessments followed by surgical procedures and pathological evaluation. Their major symptoms were otorrhea, otalgia, tinnitus, and profound hearing loss. Imaging studies showed an osteolytic soft mass with calcified debris in the inner ear, and the bony labyrinth was eroded partly or completely by granulation mass, with loss of bony morphology. Further pathological examination was coincident with inflammatory granulation tissue with some calcification or osseous tissue. The disease process is attributed to chronic osteomyelitis due to the presence of osteonecrosis. Prompt CT and MRI examinations and optimal therapeutic management facilitate definitive diagnosis and protect against fatal complications.

Atlas-Based Classification of Hyperintense Regions from MR Diffusion-Weighted Images of the Brain: Preliminary Results

The study of subjects with acquired brain damage in a specific location is important in exploring human brain function. Description of lesion locations within and across subjects is a crucial methodological component that usually involves the distinction of normal from damaged tissue (lesion segmentation) in relation to lesion locations in terms of a standard anatomical reference space (lesion mapping). Our study provides an atlas-based, computer-aided methodology for classification of hyperintense regions on diffusion-weighted images of the brain, representing either ischemic lesions or susceptibility artifacts. We applied a leave-one-out method of cross-validation that computed probabilistic atlases of true lesions and artifacts, based on training data. Our approach accurately classifies lesions and artifacts, but leaves a significant number of regions unclassified, due to the relatively small number of training samples. An initial segmentation step based on a larger sample of data sets is required to automate discrimination of lesions and artifacts.

Postmenopausal hormone therapy and subclinical cerebrovascular disease: the WHIMS-MRI Study

OBJECTIVE

The Women's Health Initiative Memory Study (WHIMS) hormone therapy (HT) trials reported that conjugated equine estrogen (CEE) with or without medroxyprogesterone acetate (MPA) increases risk for all-cause dementia and global cognitive decline. WHIMS MRI measured subclinical cerebrovascular disease as a possible mechanism to explain cognitive decline reported in WHIMS.

METHODS

We contacted 2,345 women at 14 WHIMS sites; scans were completed on 1,424 (61%) and 1,403 were accepted for analysis. The primary outcome measure was total ischemic lesion volume on brain MRI. Mean duration of on-trial HT or placebo was 4 (CEE+MPA) or 5.6 years (CEE-Alone) and scans were conducted an average of 3 (CEE+MPA) or 1.4 years (CEE-Alone) post-trial termination. Cross-sectional analysis of MRI lesions was conducted; general linear models were fitted to assess treatment group differences using analysis of covariance. A (two-tailed) critical value of alpha = 0.05 was used.

RESULTS

In women evenly matched within trials at baseline, increased lesion volumes were significantly related to age, smoking, history of cardiovascular disease, hypertension, lower post-trial global cognition scores, and increased incident cases of on- or post-trial mild cognitive impairment or probable dementia. Mean ischemic lesion volumes were slightly larger for the CEE+MPA group vs placebo, except for the basal ganglia, but the differences were not significant. Women assigned to CEE-Alone had similar mean ischemic lesion volumes compared to placebo.

CONCLUSIONS

Conjugated equine estrogen-based hormone therapy was not associated with a significant increase in ischemic brain lesion volume relative to placebo. This finding was consistent within each trial and in pooled analyses across trials.

Ligand-receptor binding measured by laser-scanning imaging

This report describes the integration of laser-scanning fluorometric cytometry and nonseparation ligand-binding techniques to provide new assay methods adaptable to miniaturization and high-throughput screening. Receptor-bound, cyanine dye-labeled ligands, [Cy]ligands, were discriminated from those free in solution by measuring the accumulated fluorescence associated with a receptor-containing particle. To illustrate the various binding formats accommodated by this technique, saturation- and competition-binding analyses were performed with [Cy]ligands and their cognate receptors expressed in CHO cells or as fusion proteins coated on polystyrene microspheres. We have successfully applied this technique to the analysis of G protein-coupled receptors, cytokine receptors, and SH2 domains. Multiparameter readouts from ligands labeled separately with Cy5 and Cy5.5 demonstrate the simultaneous analysis of two target receptors in a single well. In addition, laser-scanning cytometry has been used to assay enzymes such as phosphatases and in the development of single-step fluorescent immunoassays.

[The lateral abdominal island flap--the lateral intercostal neurovascular island flap]

This work studied the lateral abdominal island flap, its clinical value, transposition range and the practicability of a modified operative method. Five lateral abdominal island flaps were used in 5 patients. Four of them were for axillary radiation ulcers after radical mastectomy. One was for a sacral defect after resection of a recurrent fibrosarcoma. All the flaps obtained satisfactory results. Clinical applications revealed that the blood supply of the lateral abdominal skin was mainly from the lateral cutaneous branches of the 9th, 10th and 11th intercostal arteries, among which there were numerous anastomoses. The lateral abdominal island flap can be pedicled with any of these lateral cutaneous branches. The long pedicle of the flap provides a wide range of trnasposition from the axilla to the sacrum. As the pedicle of the flap contains the lateral cutaneous branch of the intercostal nerve, the flap can bring sensation function to the recipient area. The modified operative method of the lateral abdominal island flap is introduced.

Dissection of CR1, factor H, membrane cofactor protein, and factor B binding and functional sites in the third complement component

Previous studies have suggested that the residues 727-768 of human (Hu) C3 contain the binding sites for CR1, factor H, and factor B. Here, we have (1) characterized further some of the C3 structural requirements for its binding to CR1, H, and B, (2) investigated the functions associated with these C3-ligand interactions, and (3) studied the relationship of MCP-binding sites in C3 with those for CR1, H, and B. Hu C3 molecules in which residues 727-768 were deleted (designated C3delta727-768) or substituted with the corresponding segment of cobra venom factor, Xenopus, or trout C3 (chimeric C3s) were expressed in the baculovirus system and analyzed for their reactivity with C3-binding proteins. In contrast to wild-type iC3 which, in the presence of CR1, is cleaved by factor I to iC3b-a and C3c-a and C3dg, all chimeric C3s were cleaved only to iC3b-a. In addition, the cleavage of deleted (C3delta727-768) iC3 to iC3b-a by factor I in the presence of CR1 was significantly reduced, whereas it remained unaltered in the presence of MCP. Cleavage of iC3 to iC3b-a by factor I and H was similar in all expressed C3s except C3delta727-768, whose cleavage was significantly reduced. All of the expressed molecules except C3delta727-768 were capable of forming the fluid-phase alternative pathway C3 convertase, and all reacted with properdin. These results suggest that during cleavage of iC3 by factor I and CR1, or H, CR1 and H bind to at least two sites on C3 and that the MCP binding site(s) on C3b are different from those for CR1. They also indicate that some or all of the C3 residues that are directly involved in, or contribute to, the structure of one of the CR1 and H binding sites are located within residues 727-768. These studies also demonstrate that, although this segment of C3 may be involved in C3-factor B interaction, other residues in addition to 736EE (previously implicated in B binding) must also contribute significantly to this interaction.

Dissection of CR1, factor H, membrane cofactor protein, and factor B binding and functional sites in the third complement component

Previous studies have suggested that the residues 727-768 of human (Hu) C3 contain the binding sites for CR1, factor H, and factor B. Here, we have (1) characterized further some of the C3 structural requirements for its binding to CR1, H, and B, (2) investigated the functions associated with these C3-ligand interactions, and (3) studied the relationship of MCP-binding sites in C3 with those for CR1, H, and B. Hu C3 molecules in which residues 727-768 were deleted (designated C3delta727-768) or substituted with the corresponding segment of cobra venom factor, Xenopus, or trout C3 (chimeric C3s) were expressed in the baculovirus system and analyzed for their reactivity with C3-binding proteins. In contrast to wild-type iC3 which, in the presence of CR1, is cleaved by factor I to iC3b-a and C3c-a and C3dg, all chimeric C3s were cleaved only to iC3b-a. In addition, the cleavage of deleted (C3delta727-768) iC3 to iC3b-a by factor I in the presence of CR1 was significantly reduced, whereas it remained unaltered in the presence of MCP. Cleavage of iC3 to iC3b-a by factor I and H was similar in all expressed C3s except C3delta727-768, whose cleavage was significantly reduced. All of the expressed molecules except C3delta727-768 were capable of forming the fluid-phase alternative pathway C3 convertase, and all reacted with properdin. These results suggest that during cleavage of iC3 by factor I and CR1, or H, CR1 and H bind to at least two sites on C3 and that the MCP binding site(s) on C3b are different from those for CR1. They also indicate that some or all of the C3 residues that are directly involved in, or contribute to, the structure of one of the CR1 and H binding sites are located within residues 727-768. These studies also demonstrate that, although this segment of C3 may be involved in C3-factor B interaction, other residues in addition to 736EE (previously implicated in B binding) must also contribute significantly to this interaction.

Characterization of a 70-kDa, EBV gp350/220-binding protein on HSB-2 T cells

EBV binds and infects HSB-2 T cells via a receptor distinct from CD21. To further study this novel EBV receptor, we expressed the first 470 amino acids of the EBV-gp350/220 using the baculovirus expression system. The recombinant gp350/220(1-470) has a m.w. of 95 kDa, reacts with anti-gp350/220 Abs, and binds CD21 in ELISA. Radiolabeled gp350/220(1-470) binds both HSB-2 and Raji cells. The gp350/220(1-470) protein also inhibits EBV binding to both HSB-2 and Raji, detected by flow cytometry. Lysates of HSB-2 cells compete with CD21 for binding to gp350/220(1-470), suggesting that the two receptors bind related epitopes on the recombinant protein. Scatchard analysis reveals that gp350/220(1-470) binds to 34,000 high affinity sites/HSB-2 cell (Kd = 0.92 x 10(-8) M) compared with the 97,000 high affinity sites bound/Raji cell (Kd = 1.78 x 10(-8) M). Utilizing a gp350/220(1-470)-affinity matrix, we identify a 70-kDa (55-kDa nonreduced) protein on the surfaces of 125I-labeled HSB-2 cells. Binding of this protein to the matrix is inhibited by anti-gp350/220 Ab 72A1. In summary, we characterize a novel EBV-binding molecule on HSB-2 cells, compare its reactivity with gp350/220 to that of CD21, and provide evidence of a gp350/220-reactive, 70-kDa protein on the surfaces of HSB-2 cells. In view of previous evidence of HSB-2 infectivity by EBV, we propose that the 70 kDa protein represents the novel EBV receptor.

Characterization of a 70-kDa, EBV gp350/220-binding protein on HSB-2 T cells

EBV binds and infects HSB-2 T cells via a receptor distinct from CD21. To further study this novel EBV receptor, we expressed the first 470 amino acids of the EBV-gp350/220 using the baculovirus expression system. The recombinant gp350/220(1-470) has a m.w. of 95 kDa, reacts with anti-gp350/220 Abs, and binds CD21 in ELISA. Radiolabeled gp350/220(1-470) binds both HSB-2 and Raji cells. The gp350/220(1-470) protein also inhibits EBV binding to both HSB-2 and Raji, detected by flow cytometry. Lysates of HSB-2 cells compete with CD21 for binding to gp350/220(1-470), suggesting that the two receptors bind related epitopes on the recombinant protein. Scatchard analysis reveals that gp350/220(1-470) binds to 34,000 high affinity sites/HSB-2 cell (Kd = 0.92 x 10(-8) M) compared with the 97,000 high affinity sites bound/Raji cell (Kd = 1.78 x 10(-8) M). Utilizing a gp350/220(1-470)-affinity matrix, we identify a 70-kDa (55-kDa nonreduced) protein on the surfaces of 125I-labeled HSB-2 cells. Binding of this protein to the matrix is inhibited by anti-gp350/220 Ab 72A1. In summary, we characterize a novel EBV-binding molecule on HSB-2 cells, compare its reactivity with gp350/220 to that of CD21, and provide evidence of a gp350/220-reactive, 70-kDa protein on the surfaces of HSB-2 cells. In view of previous evidence of HSB-2 infectivity by EBV, we propose that the 70 kDa protein represents the novel EBV receptor.

Overexpression, purification, and characterization of third component of complement

The third component of complement (C3) plays a critical role in both pathways of complement activation by interacting with numerous other complement proteins. To elucidate the molecular features of C3 that relate to the functional activities of the molecule, we expressed the cDNA of human complement component C3 in cultured insect cells using a baculovirus expression vector system derived from the baculovirus Autographa california nuclear polyhedrosis virus (AcNPV). The expression of C3 was controlled by the promoter of the polyhedrin gene and, when recombinant baculovirus infected insect cells were cultured in serum-free medium, C3 was detected at a level of 10 micrograms/ml of culture medium. Characterization of the recombinant C3 (rC3) by SDS-PAGE revealed that the C3 gene product was translated as a 188 kDa protein comprised of two chains of 115 kDa and 73 kDa analogous to the alpha and beta chains of serum-derived human C3 (sC3). An analysis of the glycosylation pattern of purified rC3 revealed that, whereas both the alpha and beta chains were glycosylated as in sC3, the proC3 moiety of rC3 also was glycosylated. When rC3 was produced in the High Five cell line of insect cells and evaluated for reactivity with a panel of anti-C3 monoclonal antibodies (MoAb), the results suggested that the conformation of the baculovirus expressed C3 was similar to that of native C3. When the rC3 was purified by anion exchange column chromatography, it was able to react with several C3-binding proteins (CR1, P and H), reconstitute C3-deficient serum and support the activation of both complement pathways thus demonstrating that a baculovirus-expressed C3 can participate in the formation of and can be cleaved by both the classical and alternative pathway convertases. Incubation of rC3 with factor I and H revealed that both C3 and proC3 are susceptible to cleavage by factor I.

Third component of trout complement. cDNA cloning and conservation of functional sites

Of the 30 distinct complement proteins recognized to date, C3 is probably the most versatile and multifunctional molecule known, interacting with at least 20 different proteins. It plays a critical role in both pathways of complement activation and participates in phagocytic and immunoregulatory processes. Structural and functional analysis of C3 from different species, in addition to phylogenetic information, provides insights into the structural elements mediating the various functions. This study describes the cDNA cloning of one of two isoforms of the third complement component, C3-1, of rainbow trout (Salmo gairdneri) and the analysis of its functional sites. By screening a trout liver lambda gt11 library with anti-trout C3 chain-specific antibodies and polymerase chain reaction we have determined the cDNA sequence of trout C3-1. The obtained sequence is in complete agreement with the protein sequence of several tryptic peptides, corresponding to different regions of trout C3-1. C3-1 consists of 1640 amino acids with a calculated molecular mass of 181,497 Da. The sequence contains two potential N-glycosylation sites, one on each chain of C3. The deduced protein sequence showed 44.1, 43.3, 44.2, 44.9, 43.1, 43.8, 45.9, 29.9, and 33.1% amino acid identities to human, mouse rat, guinea pig, rabbit, cobra, frog, hagfish, and lamprey C3, whereas the identities to human C4, C5, and alpha 2M are 30.4, 28, and 22.9%, respectively. The trout C3 amino acid sequence shows clusters of high and low similarity to C3 from other species. In the regions of high similarity belong the C3 domains that contain the thiolester site and the properdin binding sites, whereas the regions that correspond to regions of human C3 where CR1 and CR2 bind show low amino acid sequence similarity. The deduced amino acid sequence shows that the C3 convertase cleavage site (Arg-Ser) is conserved in trout C3, whereas the factor I cleavage sites are Arg-Ala and Arg-Thr instead of Arg-Ser, which is found in the C3 of other species. Protein sequencing of the trout C3 fragments fixed on zymosan during complement activation confirmed the cleavage of trout C3 by trout C3 convertase and factor I at Arg-Ser and Arg-Thr, respectively.

Third component of trout complement. cDNA cloning and conservation of functional sites

Of the 30 distinct complement proteins recognized to date, C3 is probably the most versatile and multifunctional molecule known, interacting with at least 20 different proteins. It plays a critical role in both pathways of complement activation and participates in phagocytic and immunoregulatory processes. Structural and functional analysis of C3 from different species, in addition to phylogenetic information, provides insights into the structural elements mediating the various functions. This study describes the cDNA cloning of one of two isoforms of the third complement component, C3-1, of rainbow trout (Salmo gairdneri) and the analysis of its functional sites. By screening a trout liver lambda gt11 library with anti-trout C3 chain-specific antibodies and polymerase chain reaction we have determined the cDNA sequence of trout C3-1. The obtained sequence is in complete agreement with the protein sequence of several tryptic peptides, corresponding to different regions of trout C3-1. C3-1 consists of 1640 amino acids with a calculated molecular mass of 181,497 Da. The sequence contains two potential N-glycosylation sites, one on each chain of C3. The deduced protein sequence showed 44.1, 43.3, 44.2, 44.9, 43.1, 43.8, 45.9, 29.9, and 33.1% amino acid identities to human, mouse rat, guinea pig, rabbit, cobra, frog, hagfish, and lamprey C3, whereas the identities to human C4, C5, and alpha 2M are 30.4, 28, and 22.9%, respectively. The trout C3 amino acid sequence shows clusters of high and low similarity to C3 from other species. In the regions of high similarity belong the C3 domains that contain the thiolester site and the properdin binding sites, whereas the regions that correspond to regions of human C3 where CR1 and CR2 bind show low amino acid sequence similarity. The deduced amino acid sequence shows that the C3 convertase cleavage site (Arg-Ser) is conserved in trout C3, whereas the factor I cleavage sites are Arg-Ala and Arg-Thr instead of Arg-Ser, which is found in the C3 of other species. Protein sequencing of the trout C3 fragments fixed on zymosan during complement activation confirmed the cleavage of trout C3 by trout C3 convertase and factor I at Arg-Ser and Arg-Thr, respectively.

Evidence for multiple sites of interaction in C3 for complement receptor type 2 (C3d/EBV receptor, CD21)

Multivalent but not monovalent CR2 ligands are required to elicit Raji cell proliferation as well as other B cell responses. It has been reported (C. Servis and J. D. Lambris, J. Immunol. 1989. 142: 2207) that the tetrameric peptide T-(C31202-1214)4, which represents the CR2-binding site in C3d, was able to support Raji cell growth. We show here that the tetrameric peptide T-(gp350(19-30)4, which contains the CR2-binding site in gp350 protein of EBV also induces Raji cell growth and this effect is inhibited by the monomeric peptides gp350(19-30) and C3(1201-1214). We also investigated the nature of the interaction between C3 fragment and CR2 in order to explain the Raji cell growth-supporting effect exerted by C3. The following findings suggest that there are multiple sites in the C3 molecule able to interact with CR2: (1) both C3c and C3d immobilized on microspheres are able to bind to Raji cells through CR2. (2) soluble C3d inhibits to a greater extent the binding of CR2 to fixed C3d than to fixed C3b, which suggests the existence of additional CR2-binding sites within C3b not present in the C3d portion of the molecule; (3) synthetic peptides C3(1187-1214), C3(741-757) and C3(295-307) which represents regions of similarity in the C3 molecule bind specifically to CR2 on Raji cells and compete with each other for binding to the receptor and (4) preincubation of microtiter plate-fixed C3b with monoclonal or polyclonal anti-peptide antibodies (C3-9, anti-C3(727-768) recognize the N terminus of the alpha chain of C3 (including residues 741-757) inhibited CR2 binding. Therefore, these data suggest that the N terminus of the alpha chain of C3 is involved in binding to CR2.