ABSTRACT
@#In light of the limited protection conferred by current influenza vaccines, immunisation using universal influenza vaccines has been proposed for protection against all or most influenza sub-types. The fundamental principle of universal influenza vaccines is based on conserved antigens found in most influenza strains, such as matrix 2, nucleocapsid, matrix 1 and stem of hemagglutinin proteins. These antigens trigger cross-protective immunity against different influenza strains. Many researchers have attempted to produce the conserved epitopes of these antigens in the form of peptides in the hope of generating universal influenza vaccine candidates that can broadly induce cross-reactive protection against influenza viral infections. However, peptide vaccines are poorly immunogenic when applied individually owing to their small molecular sizes. Hence, strategies, such as combining peptides as multi-epitope vaccines or presenting peptides on vaccinia virus particles, are employed. This review discusses the clinical and laboratory findings of several multi-epitope peptide vaccine candidates and vaccinia-based peptide vaccines. The majority of these vaccine candidates have reached the clinical trial phase. The findings in this study will indeed shed light on the applicability of universal influenza vaccines to prevent seasonal and pandemic influenza outbreaks in the near future.
ABSTRACT
Each year, influenza A infections have caused tremendous death rate as high as 300,000-500,000 globally. Althoughthere are effective anti-influenza agents and vaccines, high mutational rate among influenza A viruses renders dramaticdecline in the effectiveness of anti-influenza agents or vaccines in certain individuals. The situation is further complicatedby limitations in influenza vaccine production, for instance, long production period, limited vaccine capacity and lackof cross-protection against various influenza A virus strains. To solve these issues, development of universal influenzavaccine based on conserved antigens such as non-stuctural protein 1 (NS1) has been endeavoured. NS1 protein is highlyconserved in all influenza A virus strains known by far, produced abundantly on infected cell surfaces and responsible formaintaining virulence. Furthermore, cytotoxic T-lymphocytes that are active against NS1 were also reported to be ableto avoid shedding of influenza in hosts. To better inhibit influenza infections, oral immunization has long been proposeddue to feasibility of this method to be implemented and safer for recipients while able to target influenza A viruses fromthe entry point. Lactobacillus has been vastly studied for its roles as bacterial carrier in oral vaccine development dueto its significant probiotic properties. For examples, stimulation of immune responses in oral and airway mucosal layers,high colonization in oral and airway mucosal layers and great natural adjuvant effects. In this light, influenza universaloral vaccine developed using NS1 dan Lactobacillus should be further studied in influenza oral vaccine design.
ABSTRACT
The occasional influenza pandemics and the seasonal influenza epidemics have destroyed millions of lives since the last century. It is therefore necessary to understand the virus replication patterns as this provides essential information on the virus infectivity, pathogenicity and spread patterns. This study aimed to investigate the replication of avian influenza A virus H5N1 (A/Chicken/Malaysia/5858/2004) in MDCK cells. In this study, the TCID50 (50% tissue culture infectious dose) of AIV H5N1 was first determined. The MDCK cells were then infected with AIV H5N1 at TCID50 for 0-48 h. The CPE (cytopathic effect) was observed and cell death was determined hourly. The virus-infected cells and media were subsequently collected for gene analysis. The results showed that the TCID50 of AIV H5N1 was 10-9 dilution. The CPE percentage showed a strong and positive correlation with the infection period (r = 1.0, n = 9, p 0.05) and infected cell (r = 0.73, n = 9, p < 0.05) were also positively correlated with the infection period. In conclusion, although CPE started to be observed in the early time points of infection, however, the M2 gene was only amplified from the infected media and cells after 48 h and 24 h, respectively. This signifies that AIV H5N1 used in this study is pathogenic and it is able to cause severe cytopathology to host cells even at low virus load.