Etiological surveillance of viral diarrhea from 2017 to 2019 in Zhangzhou city, Fujian province, China.

Background: Viral diarrhea is one of the major causes of morbidity and mortality in children. This study aimed to conduct etiological surveillance of viral diarrhea in Zhangzhou city, Fujian province, China, from 2017 to 2019 to identify the prevalence, distribution, and characteristics of viral pathogens causing gastrointestinal infections in the region. Methods: Stool samples were collected from patients with acute diarrhea in Zhangzhou city, Fujian province, China, from 2017 to 2019. Rotavirus, norovirus, astrovirus, and adenovirus were detected using fluorescence immunochromatography assay. Results: Of the total 5,627 samples that were collected, at least one of the viruses (rotavirus, norovirus, astrovirus and adenovirus) was found to be positive in 1,422 samples. Rotavirus, norovirus, astrovirus, and adenovirus, were detected in 53.73, 16.68, 15.52, and 14.97%, respectively. Mixed infections were determined in 17.65% of the positive samples. The predominant mixed infections observed were a combination of norovirus and astrovirus, followed by rotavirus and norovirus, and rotavirus and astrovirus. The highest positive rate was observed in the 12-23-month group for rotavirus and adenovirus, while a significantly higher positive rate was observed for norovirus and astrovirus in the 6-11-month group. Conclusion: These findings from this etiological surveillance highlight the significant burden of viral diarrhea in Zhangzhou city, with rotavirus being the predominant pathogen. The identification of common mixed infections provides insights into the complex nature of viral diarrhea transmission. Target interventions and public health strategies should be implemented, particularly during the winter and spring seasons, to prevent and control the spread of viral pathogens causing gastrointestinal infections in this region.

Wa-VP4* as a candidate rotavirus vaccine induced homologous and heterologous virus neutralizing antibody responses in mice, pigs, and cynomolgus monkeys.

Group A rotavirus (RVA) is the primary etiological agent of acute gastroenteritis (AGE) in children under 5 years of age. Despite the global implementation of vaccines, rotavirus infections continue to cause over 120,000 deaths annually, with a majority occurring in developing nations. Among infants, the P[8] rotavirus strain is the most prevalent and can be categorized into four distinct lineages. In this investigation, we expressed five VP4(aa26-476) proteins from different P[8] lineages of human rotavirus in E. coli and assessed their immunogenicity in rabbits. Among the different P[8] strains, the Wa-VP4 protein, derived from the MT025868.1 strain of the P[8]-1 lineage, exhibited successful purification in a highly homogeneous form and significantly elicited higher levels of neutralizing antibodies (nAbs) against both homologous and heterologous rotaviruses compared to other VP4 proteins derived from different P[8] lineages in rabbits. Furthermore, we assessed the immunogenicity of the Wa-VP4 protein in mice, pigs, and cynomolgus monkeys, observing that it induced robust production of nAbs in all animals. Interestingly, there was no significant difference between in nAb titers against homologous and heterologous rotaviruses in pigs and mankeys. Collectively, these findings suggest that the Wa-VP4* protein may serve as a potential candidate for a rotavirus vaccine.

GPI: An indicator for immune infiltrates and prognosis of human breast cancer from a comprehensive analysis.

Glucose-6-phosphate isomerase (GPI) plays an important part in gluconeogenesis and glycolysis through the interconversion of d-glucose-6-phosphate and d-fructose-6-phosphate, and its clinical significance still remains unclear in breast cancer (BRCA). We analyzed the expressions of GPI in BRCA patients to determine prognostic values. Our results showed that the expression levels of GPI were upregulated in BRCA patients, and a high GPI expression is correlated with poor overall survival (OS) in BRCA. At the same time, a high GPI expression is correlated with poor clinicopathological characteristics, such as stage III, over 60 years old, N3, HER2 negative, and estrogen receptor (ER) positive. Further analysis of the influence of GPI on the prognosis of BRCA suggested that 50 genes and 10 proteins were positively correlated with GPI, and these genes and proteins were mainly involved in cell cycle signaling pathways. In addition, in this study, we observed that GPI was closely related to N 6-methyladenosine (m6A) RNA methylation modification and immune cell infiltration and ferroptosis-related gene expression in BRCA, and there was a difference in m6A RNA methylation alterations, immune cell infiltration, and ferroptosis-related gene expression between the high GPI expression group and the low GPI expression group. Finally, we found that GPI in BRCA had 2.6% gene alterations, and BRCA patients with gene alteration of GPI had a poor prognosis in disease-free survival (DFS). Altogether, our work strongly suggested that GPI may serve as a new prognostic biomarker for BRCA patients.

Bivalent rotavirus VP4∗ stimulates protective antibodies against common genotypes of human rotaviruses.

Non-replicating rotavirus vaccines are an alternative strategy to improve the efficacy and safety of rotavirus vaccines. The spike protein VP4, which could be enzymatically cleaved into VP8∗ and VP5∗, is an ideal target for the development of recombinant rotavirus vaccine. In our previous studies, we demonstrated that the truncated VP4 (aa26-476, VP4∗) could be a more viable vaccine candidate compared to VP8∗ and VP5∗. Here, to develop a human rotavirus vaccine, the VP4∗ proteins of P[4], P[6], and P[8] genotype rotaviruses were expressed. All VP4∗ proteins can stimulate high levels of neutralizing antibodies in both guinea pigs and rabbits when formulated in aluminum adjuvant. Furthermore, bivalent VP4∗-based vaccine (P[8] + P[6]-VP4∗) can stimulate high levels of neutralizing antibodies against various genotypes of rotavirus with no significant difference as compared to the trivalent vaccines. Therefore, bivalent VP4∗ has the potential to be a viable rotavirus vaccine candidate for further development.

Generation and characterization of mouse monoclonal antibodies against the VP4 protein of group A human rotaviruses.

Human rotaviruses (RVs) are the leading cause of severe diarrhea in infants and young children worldwide. Among the structural proteins, as a spike protein, rotavirus VP4 plays a key role in both viral attachment and penetration. Currently, studies on monoclonal antibodies (mAbs) against VP4 are limited. In this study, mice were immunized with truncated VP4* to produce murine mAbs. In total, 50 mAbs were produced and characterized. Twenty-four mAbs were genotype-specific and 20 mAbs recognized the common VP4 epitopes shared by P[8], P[4], and P[6] viruses. Thirty-five of the 50 mAbs were neutralizing mAbs, among which nine mAbs could neutralize all three P-genotype RVs, and 10 neutralizing mAbs exhibited conformational sensitivity. Ten mAbs recognized dominant neutralizing epitopes, including the broadly neutralizing mAb 9C4 recognized conformational epitope. Further investigation shows that S376 and S464 are key amino acids for 9C4 binding, however, the exact binding sites of 9C4 remain to be fully defined. Overall, this panel of mAbs has demonstrated utility as immunodiagnostic and research reagents, and could potentially serve as crucial tools for exploring the neutralizing mechanisms and quality control of VP4* protein-based RV subunit vaccines. Further evaluation of cross-neutralizing mAbs could not only improve the understanding of the heterotypic protection conferred by RV vaccines, but also facilitate the development of broadly protective RV vaccines.

Comprehensive Analysis of Prognostic and immune infiltrates for FOXPs Transcription Factors in Human Breast Cancer.

Forkhead-box-P family include FOXP1/2/3/4 and its clinical significance still remains unclear in breast cancer (BRCA). We analysed the expressions of FOXPs in BRCA patients to determine diagnostic and prognostic values. Our results indicated that the transcriptional levels of FOXP3/4 were up-regulated in BRCA patients, but FOXP2 were down-regulated. No statistically significant correlation were found between the expression levels of FOXPs in Pathologic stage. FOXP2/3 had a significantly high AUC value in the detection of breast cancer, with 96.8% or 95.7% in accuracy respectively. Our study also suggested that BRCA patients with high transcription levels of FOXP1/2/4 were significantly associated with longer Overall Survival (OS). In contrast, BRCA patients with high transcription level of FOXP3 was not statistically related with OS. Our work revealed that FOXPs were closely related to the alteration of extensive immune checkpoints in breast invasive carcinoma. Additionally, FOXP3 has a significant positive correlation with PDCD1, CD274, CTLA4 and TMB in breast cancer, and FOXP3 expression showed a statistically significant correlation with infiltration of immune cells. Finally, we found that FOXP3 expression predicted the breast cancer cells response to anticancer drugs. Altogether, our work strongly suggested that FOXPs could serve as a biomarker for tumor detection, therapeutic design and prognosis.

Establishment of Sandwich ELISA for Quality Control in Rotavirus Vaccine Production.

Non-replicating rotavirus vaccines are alternative strategies that may improve the protective efficacy of rotavirus vaccines in low- and middle-income countries. The truncated spike protein VP4 (aa26-476, VP4*)was a candidate antigen for the development of recombinant rotavirus vaccines, with higher immunogenicity and protective efficacy compared to VP8* and VP5* alone. This article describes the development of three genotype-specific sandwich ELISAs for P[4], P[6], and P[8]-VP4*, which are important for quality control in rotavirus vaccine production. Our results showed that the detection systems had good specificity for the different genotype VP4* and were not influenced by the E. coli host proteins. Moreover, the detection systems play an important role in determining whether the target protein was contaminated by VP4* proteins of other genotypes. They can also detect the adsorption rate of the adjuvant to the P[4], P[6], P[8]-VP4* protein during the process development. The three detection systems will play an important role in the quality control and process development of VP4* based rotavirus vaccines and facilitate the development of recombinant rotavirus vaccines.

Molecular characterization of an uncommon multigene Reassortant G1P[4] rotavirus identified in China.

Rotavirus A (RVA) is the leading cause of acute gastroenteritis worldwide in both young children and animals. In this study, we analyzed the complete genome sequence of a rare G1P[4] rotavirus, which was identified from the stool samples (20130113) of an infant with diarrhea in Chongqing, China. The genotype constellation of strain 20130113 was G1-P[4]-I2-R1-C1-M1-A2-N2-T1-E1-H1. The results of both BLAST and phylogenic analysis indicated that 20130113 was likely generated by genetic reassortment between G1P[8] and G2P[4] strains that co-circulated during the season. Whether the emergence of this uncommon genotype reflects the establishment of a new RVA strain in the population requires continuous monitoring of rotavirus epidemiology.

Molecular epidemiology of group A rotavirus in outpatient diarrhea infants and children in Chongqing, China, 2011-2015.

Human group A rotavirus (RVA) is the leading cause of acute viral gastroenteritis in children under 5 years old worldwide. The aim of this study was to investigate the genotype distribution of RVA in the Midwest of China. Sentinel-based surveillance of acute diarrhea was conducted at Children's Hospital of Chongqing Medical University from 2011 to 2015. RVA was tested by using enzyme-linked immunosorbent assays. The partial VP4 genes and VP7 genes of rotavirus were amplified and sequenced, and genotyping and phylogenetic analyses were performed. Among the 2236 stool specimens collected from children with acute gastroenteritis, 681 (30.46%) were positive for RVA. The majority of children (89.28%) who tested positive for RVA were children aged ≤2 years. The seasonal peak of RVA was in the winter. As for genotype, four strain combinations, G9P[8], G3P[8], G1P[8], and G2P[4] contributed to 75.62% (515/681) of the RVA-associated diarrhea cases. After a marked increase in G9P[8] (30.77%) in 2013, G9P[8] became the predominant genotype in 2014 and 2015, whilst the prevalence of G1P[8] was decreased to 2.72% in 2015. Unusual G-P combinations (eg, G1P[4], G9P[4], G4P[6], G3P[4], G2P[8]) were also detected sporadically over the study period. Phylogenetic tree analysis results showed that the VP7 sequences of G9 strains were clustered into two main lineages, and 77.34% of them were clustered into lineage VI, with the highest nucleotide similarity to the strain JS12-17(China). VP4 gene sequences of P[8] strains were almost P[8]-lineage 3. Substantial temporal variation in the circulation of various genotypes of rotavirus in Chongqing was observed during 2011-2015, and highlights the need for continuous surveillance of RVA infection for better understanding and control of RVA infection.

The distinct impact of maternal antibodies on the immunogenicity of live and recombinant rotavirus vaccines.

A high titre of maternal antibodies is one of the possible factors associated with decreased rotavirus vaccine efficacy in low-income countries where rotavirus-associated morbidity and mortality are high. Although some studies show a negative correlation between maternal antibody levels and seroconversion after vaccination, withholding breastfeeding does not improve rotavirus vaccine efficacy. Different types of recombined vaccines were developed as an alternative to produce higher protection in developing areas. In previous studies, we found that recombinantly expressed, truncated VP4* can stimulate high titres of neutralizing antibodies and can confer protection against rotavirus infections and rotavirus-induced diarrhoea. In this study, the impact of maternal antibodies on live and recombinant rotavirus vaccines (VP4*) was evaluated in a mouse model. Dams were infected orally with murine rotavirus 7 days after delivery to mimic a natural rotavirus infection in infants and to evaluate the separate effects of trans-placentally acquired and milk-acquired maternal antibodies, pups were half exchanged. After immunization with live rotavirus, both the neutralizing antibody and IgA antibody responses were inhibited by maternal antibodies, especially by milk antibodies; however, the neutralizing antibody responses after immunization with recombinant VP4* were enhanced. In addition, the in vitro incubation of VP4* with immune sera of rotavirus could also enhance the immune responses could also enhance the immune responses. Our finding provides a basis for the development of non-replicating vaccines to address the problem of live attenuated vaccines in low- and middle-income countries.

[Polymerization and evaluation of the protective efficacy of rotavirus VP4* proteins].

In previous studies, we found that truncated rotavirus VP4* (aa 26-476) could be expressed in soluble form in Escherichia coli and confer high protection against rotavirus in the mouse mode. In this study, we further improved the immunogenicity of VP4* by polymerization. The purified VP4* was polymerized through incubation at 37 ℃ for 24 h, and then the homogeneity of the particles was analyzed by HPLC, TEM and AUC, while the thermal stability and antigenicity was analyzed by DSC and ELISA, respectively. Finally, the immunogenicity and protective efficacy of the polymers analyzed by a mouse maternal antibody model. The results showed that VP4* aggregated into homogeneous polymers, with high thermostability and neutralizing antibody binding activity. In addition, VP4* polymers (endotoxin <20 EU/dose) stimulated higher neutralizing antibodies and confer higher protection against rotavirus-induced diarrhoea compared with the VP4* trimers when immunized with aluminium adjuvant. In summary, the study in VP4* polymers provides a new strategy for the development of recombinant rotavirus vaccines.

Inflammatory pseudotumor-like follicular dendritic cell sarcoma: A brief report of two cases.

BACKGROUND: Follicular dendritic cell (FDC) sarcoma/tumor is a rare malignant tumor of follicular dendritic cells, which is considered a low-grade sarcoma that can involve lymph nodes or extranodal sites. Conventional FDC sarcomas are negative for Epstein-Barr virus (EBV), whereas the inflammatory pseudotumor-like variant consistently shows EBV in the neoplastic cells. CASE SUMMARY: We report two cases of inflammatory pseudotumor-like FDC sarcoma in the liver that received 3D laparoscopic right hepatectomy and open right hepatectomy separately. CONCLUSION: EBV probe-based in situ hybridization and detection of immunohistochemical markers of FDC play an important role in the diagnosis and differential diagnosis of inflammatory pseudotumor-like FDC sarcoma. Complete surgical excision combined with regional lymphadenectomy may be effective in reducing the postoperative recurrence and metastasis and improving long-term survival rates.

Expression and characterization of a novel truncated rotavirus VP4 for the development of a recombinant rotavirus vaccine.

The outer capsid protein VP4 is an important target for the development of a recombinant rotavirus vaccine because it mediates the attachment and penetration of rotavirus. Due to the poor solubility of full-length VP4, VP8 was explored as candidate rotavirus vaccines in the past years. In previous studies, it has been found that the N-terminal truncated VP8 protein, VP8-1 (aa26-231), could be expressed in soluble form with improved immunogenicity compared to the core of VP8 (aa65-223). However, this protein stimulated only a weak immune response when aluminum hydroxide was used as an adjuvant. In addition, it should be noted that the protective efficacy of VP4 was higher than that of VP8 and VP5. In this study, it was found that when the N-terminal 25 amino acids were deleted, the truncated VP4∗ (aa26-476) containing VP8 and the stalk domain of VP5 could be expressed in soluble form in E. coli and purified to homogeneous trimers. Furthermore, the truncated VP4 could induce high titers of neutralizing antibodies when aluminum adjuvant was used and conferred high protective efficacy in reducing the severity of diarrhea and rotavirus shedding in stools in animal models. The immunogenicity of the truncated VP4 was significantly higher than that of VP8∗ and VP5∗ alone. Taken together, the truncated VP4∗ (aa26-476), with enhanced immunogenicity and immunoprotectivity, could be considered as a viable candidate for further development and has the potential to become a parenterally administered rotavirus vaccine.

Immunogenicity and protective efficacy of rotavirus VP8* fused to cholera toxin B subunit in a mouse model.

In attempts to develop recombinant subunit vaccines against rotavirus disease, it was previously shown that the N-terminal truncated VP8* protein, VP8-1 (aa26-231), is a good vaccine candidate when used for immunization in combination with Freund's adjuvant. However, this protein stimulated only weak immune response when aluminum hydroxide was used as an adjuvant. In this study, the nontoxic B subunit of cholera toxin (CTB) was employed as intra-molecular adjuvant to improve the immunogenicity of VP8-1. Both, the N-terminal and C-terminal fusion proteins, were purified to homogeneity, at which stage they formed pentamers, and showed significantly higher immunogenicity and protective efficacy than a VP8-1/aluminum hydroxide mixture in a mouse model. Compared to VP8-1-CTB, CTB-VP8-1 showed higher binding activity to both, GM1 and the conformation sensitive neutralizing monoclonal antibodies specific to VP8. More importantly, CTB-VP8-1 elicited higher titers of neutralizing antibodies and conferred higher protective efficacy than VP8-1-CTB. Therefore, the protein CTB-VP8-1, with enhanced immunogenicity and immunoprotectivity, could be considered as a viable candidate for further development of an alternative, replication-incompetent, parenterally administered vaccine against rotavirus disease.

Characterization and protective efficacy in an animal model of a novel truncated rotavirus VP8 subunit parenteral vaccine candidate.

The cell-attachment protein VP8* of rotavirus is a potential candidate parenteral vaccine. However, the yield of full-length VP8 protein (VP8*, residues 1-231) expressed in Escherichia coli was low, and a truncated VP8 protein (ΔVP8*, residues 65-231) cannot elicit efficient protective immunity in a mouse model. In this study, tow novel truncated VP8 proteins, VP8-1 (residues 26-231) and VP8-2 (residues 51-231), were expressed in E. coli and evaluated for immunogenicity and protective efficacy, compared with VP8* and ΔVP8*. As well as ΔVP8*, the protein VP8-1 and VP8-2 were successfully expressed in high yield and purified in homogeneous dimeric forms, while the protein VP8* was expressed with lower yield and prone to aggregation and degradation in solution. Although the immunogenicity of the protein VP8*, VP8-1, VP8-2 and ΔVP8* was comparable, immunization of VP8* and VP8-1 elicited significantly higher neutralizing antibody titers than that of VP8-2 and ΔVP8* in mice. Furthermore, when assessed using a mouse maternal antibody model, the efficacy of VP8-1 to protect against rotavirus-induced diarrhea in pups was comparable to that of VP8*, both were dramatically higher than that of VP8-2 and ΔVP8*. Taken together, the novel truncated protein VP8-1, with increased yield, improved homogeneity and high protective efficacy, is a viable candidate for further development of a parenterally administrated prophylactic vaccine against rotavirus infection.