Prevalence and genomic analysis of t203-like G9 (G9-VI) rotaviruses circulating in children with gastroenteritis in Beijing, China.

Our previous surveillance revealed that t203-like G9 (tentatively designated subtype G9-VI) rotaviruses re-emerged in 2010 in Beijing and rapidly prevailed over the G9-III subtype (the most common G9 subtype globally) and previously predominant G genotypes over the following two years. G9-VI belongs to the VP7 evolutionary lineage VI, which includes unusual and sporadic human rotaviruses from China (t203) and Japan. To obtain insight into the epidemiology, evolution, and transmission advantages of G9-VI rotavirus, we performed follow-up surveillance (2014-2017) and whole-genome analysis of 12 representative G9 strains. The results showed that the G9 genotype was predominant (77.4%), with a marked increase in prevalence (previously 43.5%). Within the G9 genotype, subtype G9-VI accounted for the majority (98.3%) of cases. The most prevalent P-genotype was P[8] (93.7%), within which subtype P[8]b was rare (0.7%). Phylogenetically, the G9-VI subtype strains in this study clustered closely with contemporary emerging human rotaviruses from many other countries in VP7 lineage VI, indicating that this subtype is capable of spreading globally. These currently emerging G9-VI rotaviruses formed a distinct monophyletic subcluster when compared to early G9-VI rotaviruses. Furthermore, four specific amino acid substitutions and synonymous codon substitutions were observed in the VP7 genes between the current G9-VI and globally common G9-III rotaviruses. The remaining nine genes of all of the analyzed representative G9 strains, whether G9-VI or G9-III, combined with the P[8]a, P[8]b, or P[6] genotype and exhibited the same Wa-like backbone constellation.

Correlation analysis of IGF-1, ZAG, nesfatin-1, HbA1c levels, and type 2 diabetes mellitus complicated with hypothyroidism.

ABSTRACT: To analyze the correlation between IGF-1, ZAG, nesfatin-1, HbA1c levels, and type 2 diabetes mellitus (T2DM) complicated with hypothyroidism.Fifty-five patients with type-2 diabetes who were admitted to our hospital from August 2018 to February 2020 were selected as the control group, and 55 patients with type 2 diabetes combined with hypothyroidism who were admitted to the hospital at the same period were selected as the combined group, and 56 patients who came to our hospital for physical examination at the same period were selected as the healthy group. The general clinical data and relevant laboratory indexes of all patients in the three groups were collected and statistically analyzed. Besides, the correlation between IGF-1, ZAG, nesfatin-1, HbA1c levels, and T2DM complicated with hypothyroidism was analyzed.Levels of FPG, FINS, TC, TG, LDL, 2hPBG, TPOAb, TgAb, and HOMA-IR in the diabetes group and combined group were all significantly higher than those in the healthy group, while HDL and T4 levels in the diabetes group and combined group were lower than those in the healthy group (P < .05). The levels of FPG, FINS, TC, TG, LDL, 2hPBG, TPOAb, and TgAb in the combined group were significantly higher than those in the diabetes group (P < .05), and the levels of HDL and T4 were lower than those in the diabetes group. In addition, the IGF-1 level was positively correlated with ZAG, nesfatin-1, and HbA1c levels in the combined group (P < .05), and IGF-1 (OR: 0.964, 95% CI: 0.943-0.983, P = .001), ZAG (OR: 1.298, 95% CI: 1.121-1.401, P = .005), nesfatin-1 (OR: 0.876, 95% CI: 0.751-0.901, P = .002), and HbA1c (OR: 1.321, 95% CI: 1.121-1.401, P = .012) were independent risk factors for T2DM complicated with hypothyroidism.Regular detection of IGF-1, ZAG, nesfatin-1, and HbA1c levels are of great value for the diagnosis and treatment of patients with T2DM complicated with hypothyroidism.

Targeted mutation of p53 and Rb in mesenchymal cells of the limb bud produces sarcomas in mice.

Mice bearing germ line mutations of p53 develop sarcomas at a significant rate. Since they are susceptible to a variety of other malignancies, they are not ideally suited to the study of sarcomas. To test the possibility that targeted mutation of tumor suppressor genes in early mesenchymal cells would induce formation of sarcomas, the Prx1-cre transgenic mouse was crossed to mice-bearing floxed alleles of p53 and Rb. Mice with homozygous deletion of p53 (Prx1-cre p53(lox/lox)) developed sarcomas in the extremities at a mean time of 50 weeks. Osteosarcomas (OS) were the most common type of sarcoma (61%) followed by poorly differentiated soft tissue sarcomas (PDSTS) (32%). Homozygous deletion of p53 produced sarcomas significantly more rapidly than heterozygous deletion, which resulted in sarcoma formation after a mean of 96 weeks. Mice with homozygous Rb mutation (Prx1-cre Rb(lox/lox)) developed normally and had no ostensible defects in the limbs. In contrast to p53, targeted deletion of Rb did not produce sarcomas in the limbs. However, simultaneous deletion of Rb and p53 accelerated the time to sarcoma formation, and a greater percentage of PDSTS were found. Deletion of p53 in committed osteoblasts by the Col1a1-cre transgenic mouse bearing an osteoblast-specific enhancer resulted in a high percentage of OS. These findings suggest that deletion of p53 in mesenchymal cells that give rise to osteoblasts is a powerful initiator of OS. Deletion of Rb does not initiate sarcoma formation in mice, but it accelerates formation of both soft tissue sarcomas and OS.

Prospective head-movement correction for high-resolution MRI using an in-bore optical tracking system.

In MRI of the human brain, subject motion is a major cause of magnetic resonance image quality degradation. To compensate for the effects of head motion during data acquisition, an in-bore optical motion tracking system is proposed. The system comprises two MR-compatible infrared cameras that are fixed on a holder right above and in front of the head coil. The resulting close proximity of the cameras to the object allows precise tracking of its movement. During image acquisition, the MRI scanner uses this tracking information to prospectively compensate for head motion by adjusting the gradient field direction and radio frequency (RF) phases and frequencies. Experiments performed on subjects demonstrate robust system performance with translation and rotation accuracies of 0.1 mm and 0.15 degrees, respectively.

EWS-FLI1 induces developmental abnormalities and accelerates sarcoma formation in a transgenic mouse model.

Ewing's sarcoma is characterized by the t(11;22)(q24:q12) reciprocal translocation. To study the effects of the fusion gene EWS-FLI1 on development and tumor formation, a transgenic mouse model was created. A strategy of conditional expression was used to limit the potentially deleterious effects of EWS-FLI1 to certain tissues. In the absence of Cre recombinase, EWS-FLI1 was not expressed in the EWS-FLI1 transgenic mice, and they had a normal phenotype. When crossed to the Prx1-Cre transgenic mouse, which expresses Cre recombinase in the primitive mesenchymal cells of the embryonic limb bud, the EF mice were noted to have a number of developmental defects of the limbs. These included shortening of the limbs, muscle atrophy, cartilage dysplasia, and immature bone. By itself, EWS-FLI1 did not induce the formation of tumors in the EF transgenic mice. However, in the setting of p53 deletion, EWS-FLI1 accelerated the formation of sarcomas from a median time of 50 to 21 weeks. Furthermore, EWS-FLI1 altered the type of tumor that formed. Conditional deletion of p53 in mesenchymal cells (Prx1-Cre p53(lox/lox)) produced osteosarcomas as the predominant tumor. The presence of EWS-FLI1 shifted the tumor phenotype to a poorly differentiated sarcoma. The results taken together suggest that EWS-FLI1 inhibits normal limb development and accelerates the formation of poorly differentiated sarcomas.