Vacunas contra el virus chikungunya: avances y perspectivas

El virus chikungunya (CHIKV) es un alfavirus cuya infección provoca una enfermedad caracterizada principalmente por fiebre y dolores articulares/musculares. Entre 25-50% de las infecciones se presentan con enfermedad crónica que puede durar de meses a años. El primer brote de CHIKV en Paraguay corresponde al año 2015, siendo el último en el año 2022/2023. Diversos candidatos vacunales contra CHIKV se encuentran en diferentes etapas de desarrollo, e incluso recientemente (noviembre/2023) fue aprobada la primera vacuna contra CHIKV llamada VLA1553 (Ixchiq). Adicionalmente, al menos 30 candidatos vacunales se encuentran en ensayos preclínicos/clínicos. Con la aprobación de la primera vacuna contra CHIKV y la posibilidad de otras que lleguen al mercado prontamente, debido al estado avanzado de otros candidatos vacunales, se abrirá un nuevo escenario en esta enfermedad. Se espera que la introducción de vacunas efectivas genere un avance importante para la prevención de esta enfermedad, disminuyendo los casos agudos y los efectos crónicos de la infección por el virus. En este trabajo de revisión se analiza el avance de las vacunas contra CHIKV, además de examinar los desafíos de vigilancia epidemiológica que plantean la introducción de estas vacunas.

Chikungunya virus (CHIKV) is an alphavirus that causes an illness characterized mainly by fever and joint/muscle pain. Between 25-50% of infections present with chronic diseases that can last from months to years. The first outbreak of CHIKV in Paraguay occurred in 2015, with the last outbreak occurring in 2022/2023. Several vaccine candidates against CHIKV are in different stages of development, and even recently (November/2023), the first vaccine against CHIKV, called VLA1553 (Ixchiq), was approved. In addition, at least 30 vaccine candidates are available for preclinical and clinical trials. With the approval of the first vaccine against CHIKV and the possibility of others coming to the market soon, due to the advanced status of other vaccine candidates, a new scenario will open for this disease. The introduction of effective vaccines is expected to generate an important advance in the prevention of this disease, reducing acute cases and the chronic effects of viral infection. This review analyzes the progress of CHIKV vaccines and examines the epidemiological surveillance challenges posed by the introduction of these vaccines.

Investigation of Chikungunya virus genotype at tertiary care center in Western Maharashtra, India

Background & objectives: Chikungunya is a reemerging arbovirus infection. Laboratory diagnosis can be done by Classical test involving Rapid Immunochromatography, Enzyme-Linked Immunosorbent assay and Molecular methods. The present study was undertaken to know the genotype of the Chikungunya virus (CHICKV) among patients suspected of CHICKV and investigated by virus culture, partial sequencing, Rapid Immunochromatography, and Enzyme-linked Immunosorbent assay (ELISA). To understand different techniques used in Chikungunya diagnosis viz., virus culture, partial sequencing along with Immunochromatography and ELISA. Methods: This is a prospective, laboratory-based study at a tertiary care center. Lateral flow chromatography and ELISA was carried out on serum samples. All 50 samples were cultured and indirect Immunofluorescence was performed on positive samples at Interactive Research School for Health Affairs (IRSHA), Bharati Vidyapeeth Medical College Pune, Maharashtra, India. Virus isolates were subjected to partial sequencing for identification of genotype after confirmation by PCR. Statistical Package of Social Science (SPSS) version 22.0 software was used to calculate the Receiver operating curve (ROC) for different tests. Results: Out of 50 samples, 20 were positive by Immunochromatography, 23 by ELISA, and 3 by culture, PCR confirmed CHIKV isolates and sequencing identified genotypes as East Central South African type. Interpretation & conclusion: CHIKV culture isolates of East Central South African type lineage were predominantly found in the present study. These are also common genotypes present in Asia including India.

Influence of host genetic polymorphisms involved in immune response and their role in the development of Chikungunya disease: a review

Chikungunya virus (CHIKV) is transmitted by the bite of infected mosquitoes and can cause significant pathogenicity in humans. Moreover, its importance has increased in the Americas since 2013. The primary vectors for viral delivery are the mosquito species Aedes aegypti and Aedes albopictus. Several factors, including host genetic variations and immune response against CHIKV, influence the outcomes of Chikungunya disease. This work aimed to gather information about different single nucleotide polymorphisms (SNPs) in genes that influence the host immune response during an infection by CHIKV. The viral characteristics, disease epidemiology, clinical manifestations, and immune response against CHIKV are also addressed. The main immune molecules related to this arboviral disease elucidated in this review are TLR3/7/8, DC-SIGN, HLA-DRB1/HLA-DQB1, TNF, IL1RN, OAS2/3, and CRP. Advances in knowledge about the genetic basis of the immune response during CHIKV infection are essential for expanding the understanding of disease pathophysiology, providing new genetic markers for prognosis, and identifying molecular targets for the development of new drug treatments.

Molecular aspects of Chikungunya virus infections in cancer patients

BACKGROUND Chikungunya virus (CHIKV) is an arbovirus that can cause chronic and debilitating manifestations. The first autochthonous case in Rio de Janeiro state was diagnosed in 2015, and an outbreak was declared in 2016. OBJECTIVE The aim of this work was to evaluate CHIKV viral load in serum, plasma and urine in cancer patients to determine the best sample for diagnosis, as well as perform molecular characterisation and phylogenetic analysis of circulating strains. METHODS Paired serum, plasma and urine collected from 31 cancer patients were tested by real-time quantitative polymerase chain reaction (qPCR) and a segment of the CHIKV E1 gene was sequenced. FINDINGS We detected 11 CHIKV+ oncological patients. Paired samples analyses of nine patients showed a different pattern of detection. Also, a higher viral load in plasma (6.84 log10) and serum (6.07 log10) vs urine (3.76 log10) was found. Phylogenetic analysis and molecular characterisation revealed East/Central/Southern Africa (ECSA) genotype circulation and three amino acids substitutions (E1-K211T, E1-M269V, E1-T288I) in positive patients. MAIN CONCLUSION The results indicate the bioequivalence of serum and plasma for CHIKV diagnosis, with urine being an important complement. ECSA genotype was circulating among patients in the period of the 2016 outbreak with K211T, M269V and T288I substitution.

Antiviral activity of ethanolic extract of Nilavembu Kudineer against dengue and chikungunya virus through in vitro evaluation

BackgroundCurrently, no vaccines or modern drugs are available for dengue and chikungunya and only symptomatic relief is provided to the patients. Siddha medicine, a traditional form of indigenous medical system uses specific polyherbal formulations for the treatment of such infections with considerable success. One such polyherbal formulation for the treatment of chikungunya and dengue is Nilavembu kudineer (NVK). The mechanistic details of this drug as an antiviral for chikungunya virus (CHIKV) and dengue virus (DENV) is poorly understood.ObjectivesThe current study was undertaken to study the efficacy of NVK as an antiviral formulation against CHIKV and DENV.Materials and methodsCytotoxicity assays (MTT) were performed to determine the role of NVK as an antiviral during chikungunya and dengue infections in the following conditions-i). post infection, ii). during active infections and iii) protective, not allowing virus infection.ResultsIt was observed that NVK provides protection against CHIKV and DENV-2 during active infection as well can help to prevent virus infection in the cells and it mainly depends on the cellular availability of drugs for maximum protection against both the infections.ConclusionOur study establishes that extraction protocols are important to ensure maximum efficacy of NVK along with the time of addition of the drug during CHIKV and DENV infections in the cells. This study provides insights to the possible mode of action of NVK in in vitro condition during CHIKV and DENV infection.

Laboratory surveillance of chikungunya in Madhya Pradesh, India (2016-2017)

Background & objectives: Chikungunya (CHIK) is a neglected, re-emerging arboviral disease. Limited information on CHIK-confirmed cases during interepidemic period is available from India. This surveillance study was conducted in Madhya Pradesh (MP), India, during the years 2016-2017, to provide information about CHIK cases. Methods: Blood samples collected from patients suspected having CHIK were tested by immunoglobulin (Ig) IgM ELISA or real time reverse transcription-polymerase chain reaction (rRT-PCR) for the detection of CHIK virus (CHIKV)-specific IgM antibodies or viral RNA, respectively. Partial envelope-1 gene sequencing was done. Clinical and demographic data were collected and analyzed. Results: Of the 4019 samples tested, 494 (12.2%) were found positive for CHIKV infection. The positivity was detected in both rural and urban areas. The mean age of CHIK-positive cases was 33.12�.25 yr. Headache and joint pain were the most prominent symptoms, 34.6 per cent (171/494) of the CHIK cases required hospitalization and six patients with CHIKV infection died. The East/Central/South African genotype of CHIKV was found to be circulating in the study area. Interpretation & conclusions: Our study recorded a higher CHIK positivity during 2016-2017 in comparison to earlier reports from MP, India. A high proportion of CHIK cases required hospitalization and deaths were also reported, which indicated the severity of the disease in the study area. In-depth molecular analysis of the virus and other risk factors is essential to understand the trends in disease severity.

Genomic surveillance of the Chikungunya Virus (CHIKV) in Northeast Brazil after the first outbreak in 2014

Abstract INTRODUCTION: We performed an epidemiological surveillance of the Chikungunya (CHIKV) lineages in Bahia after the 2014 East/Central/South African (ECSA) genotype outbreak. METHODS: Reverse-transcription polymerase chain reaction (RT-PCR), viral isolation, and phylogenetic analyses were conducted on serum samples from 605 patients with CHIKV-like symptoms during 2014-2018. RESULTS: Of the 605 samples, 167 were CHIKV-positive. Viral isolation was achieved for 20 samples; their phylogenetic analysis (E2 protein) revealed the presence of ECSA lineage and reinforced the phylogenetic relationship between ECSA and Indian Ocean lineages. CONCLUSIONS: The genomic surveillance of CHIKV showed that only ECSA lineage circulated in Bahia since the 2014 outbreak.

Encephalitis associated with inappropriate antidiuretic hormone secretion due to chikungunya infection in Recife, State of Pernambuco, Brazil

Abstract The symptoms of chikungunya virus (CHIKV) infection include fever, headache, muscle aches, skin rash, and polyarthralgia, characterized by intense pain, edema, and temporary functional impairment. This is the first report of encephalitis caused by CHIKV infection associated with an atypical presentation of syndrome of inappropriate antidiuretic hormone secretion, evolving to cognitive impairment and apraxia of speech.

Chikungunya: La arbovirosis que recorre la geografía nacional

La fiebre chikungunya es la enfermedad cuyo agente etiológico es un virus trasmitido por mosquitos. Se trata de una infección que produce un síndrome febril agudo, cefalea intensa y severos dolores articulares. Su presentación inicial es muy parecida al dengue y a otras virosis trasmitidas por artrópodos. La mayoría de las personas que se infectan manifiestan síntomas por lo que la infección asintomática es rara. Lo frecuente es un comienzo con signos de la enfermedad de 3 a 7 días después de la inoculación del virus por el mosquito hembra. La primera descripción de la enfermedad se efectuó en Tanzania en 1952, durante un brote epidémico en el sur de ese país. La fiebre chikungunya llegó a las Américas por la isla San Martin, en diciembre del año 2013, extendiéndose rápidamente por el continente y el seis junio de 2014, se identificó el primer caso en Venezuela. Se describe el agente etiológico, sus vectores, patogenia y órganos blanco, así como la epidemiología, manifestaciones y formas clínicas en los diferentes grupos etarios y en la embarazada. También se revisan los factores predictivos de la fase crónica y un resumen de las citocinas, quimiocinas e interferones para mejor comprensión de los aspectos inmunes que participan en esta patología. Se finaliza con aspectos sobre diagnóstico, tratamiento y prevención de esta arbovirosis, y se completa la revisión con un caso clínico típico de la consulta de la Cátedra de Medicina Tropical, que permite una visión integral de la enfermedad.

Chikungunya's fever is a disease whose etiologic agent is a virus transmitted by mosquitoes. It is an infection that produces an acute fever, severe headache and joint pain. His initial presentation is very similar to dengue and other viral diseases transmitted by arthropods. Most people who become infected have symptoms so that asymptomatic infection is rare. Signs of the disease begin 3 to 7 days after virus inoculation by the female mosquito. The first description of the disease took place in Tanzania in 1952 during an outbreak in the south of the country. Chikungunya reached the Americas, by the San Martin island, in December 2013, spreading quickly across the continent and June 6, 2014, the first case in Venezuela was diagnosed. We are describing the etiologic agent, vectors involved, pathogenesis and organs involved. Also, epidemiology, clinical manifestations and forms in different age groups and in pregnant women. Predictors of chronic phase and a summary of cytokines, chemokines and interferons for better understanding of the immune aspects involved in this disease are also reviewed. We conclude with diagnosis, treatment and prevention, and the review is completed with a typical clinical case attended at the Tropical Medicine Department Consultation office, which permits a comprehensive view of the disease.

Western Blot Detection of Human Anti-Chikungunya Virus Antibody with Recombinant Envelope 2 Protein

Chikungunya virus (CHIKV), a tropical pathogen, has re-emerged and has massive outbreaks abruptly all over the world. Containing many dominant epitopes, the envelope E2 protein of CHIKV has been explored for the vaccination or diagnosis. In the present study, the antigenicity of a recombinant expressed intrinsically disorder domain (IUD) of E2 was tested for the detection of the antibody against CHIKV through western blot method. The gene of the IUD of E2 was inserted into 2 different vectors and expressed as recombinant GST-E2 and recombinant MBP-E2 fusion protein, respectively. Two kinds of fusion proteins were tested with 30 CHIKV patient sera and 30 normal sera, respectively. Both proteins were detected by 25 patients sera (83.3%) and 1 normal serum (3.3%). This test showed a relatively high sensitivity and very high specificity of the recombinant E2 proteins to be used as diagnostic antigens against CHIKV infection.

Serratia odorifera mediated enhancement in susceptibility of Aedes aegypti for chikungunya virus.

Background & objectives: The susceptibility of the mosquito to the invading pathogen is predominantly dictated by the complex interactions between the mosquito midgut and the surface proteins of the invading pathogen. It is well documented that the midgut microbiota plays an important role in determining the susceptibility of the mosquito to the pathogen. In the present study, we investigated the influence of Serratia odorifera, an endogenous cultivable midgut inhabitant of Aedes aegypti on the chikungunya virus (CHIKV) susceptibility to this mosquito. Methods: Ae. aegypti females free of gutflora were co-fed with CHIKV and either of the two midgut inhabitants namely, S. odorifeara and Microbacterium oxydans. CHIKV dissemination was checked on 10th day post feeding (DPF) using indirect immunoflurescence assay and plaque assay. CHIKV interacting proteins of the mosquito midgut were identified using virus overlay protein binding assay and MALDI TOF/TOF analysis. Results: The observations revealed that co-feeding of S. odorifera with CHIKV significantly enhanced the CHIKV susceptibility in adult Ae. aegypti, as compared to the mosquitoes fed with CHIKV alone and CHIKV co-fed with another midgut inhabitant, M. oxydans. Virus overlay protein binding assay (VOPBA) results revealed that porin and heat shock protein (HSP60) of Ae. aegypti midgut brush border membrane fraction interacted with CHIKV. Interpretation & conclusions: tThe results of this study indicated that the enhancement in the CHIKV susceptibility of Ae. aegypti females was due to the suppression of immune response of Ae. aegypti as a result of the interaction between S. odorifera P40 protein and porin on the gut membrane.

Chikungunya virus, epidemiology, clinics and phylogenesis: A review

Chikungunya virus is a mosquito-transmitted alphavirus that causes chikungunya fever, a febrile illness associated with severe arthralgia and rash. Chikungunya virus is transmitted by culicine mosquitoes; Chikungunya virus replicates in the skin, disseminates to liver, muscle, joints, lymphoid tissue and brain, presumably through the blood. Phylogenetic studies showed that the Indian Ocean and the Indian subcontinent epidemics were caused by two different introductions of distinct strains of East/Central/South African genotype of CHIKV. The paraphyletic grouping of African CHIK viruses supports the historical evidence that the virus was introduced into Asia from Africa. Phylogenetic analysis divided Chikungunya virus isolates into three distinct genotypes based on geographical origins: the first, the West Africa genotype, consisted of isolates from Senegal and Nigeria; the second contained strains from East/Central/South African genotype, while the third contained solely Asian. The most recent common ancestor for the recent epidemic, which ravaged Indian Ocean islands and Indian subcontinent in 2004 - 2007, was found to date in 2002. Asian lineage dated about 1952 and exhibits similar spread patterns of the recent Indian Ocean outbreak lineage, with successive epidemics detected along an eastward path. Asian group splitted into two clades: an Indian lineage and a south east lineage. Outbreaks of Chikungunya virus fever in Asia have not been associated necessarily with outbreaks in Africa. Phylogenetic tools can reconstruct geographic spread of Chikungunya virus during the epidemics wave. The good management of patients with acute Chikungunya virus infection is essential for public health in susceptible areas with current Aedes spp activity.

Chikungunya virus, epidemiology, clinics and phylogenesis: A review

Chikungunya virus is a mosquito-transmitted alphavirus that causes chikungunya fever, a febrile illness associated with severe arthralgia and rash. Chikungunya virus is transmitted by culicine mosquitoes; Chikungunya virus replicates in the skin, disseminates to liver, muscle, joints, lymphoid tissue and brain, presumably through the blood. Phylogenetic studies showed that the Indian Ocean and the Indian subcontinent epidemics were caused by two different introductions of distinct strains of East/Central/South African genotype of CHIKV. The paraphyletic grouping of African CHIK viruses supports the historical evidence that the virus was introduced into Asia from Africa. Phylogenetic analysis divided Chikungunya virus isolates into three distinct genotypes based on geographical origins: the first, the West Africa genotype, consisted of isolates from Senegal and Nigeria; the second contained strains from East/Central/South African genotype, while the third contained solely Asian. The most recent common ancestor for the recent epidemic, which ravaged Indian Ocean islands and Indian subcontinent in 2004 - 2007, was found to date in 2002. Asian lineage dated about 1952 and exhibits similar spread patterns of the recent Indian Ocean outbreak lineage, with successive epidemics detected along an eastward path. Asian group splitted into two clades: an Indian lineage and a south east lineage. Outbreaks of Chikungunya virus fever in Asia have not been associated necessarily with outbreaks in Africa. Phylogenetic tools can reconstruct geographic spread of Chikungunya virus during the epidemics wave. The good management of patients with acute Chikungunya virus infection is essential for public health in susceptible areas with current Aedes spp activity.

Approaches to the treatment of disease induced by chikungunya virus.

Chikungunya virus, a re-emerging mosquito-borne alphavirus, causes fever, rash and persistent arthralgia/arthritis in humans. Severe outbreaks have occurred resulting in infections of millions of people in Southeast Asia and Africa. Currently there are no antiviral drugs or vaccines for prevention and treatment of chikungunya infections. Herein we report the current status of research on antiviral drugs and vaccines for chikungunya virus infections.